Control method and device of heating equipment, heating equipment and storage medium

By setting multiple air outlets in the heating equipment and using temperature sensors and a control system to adjust the power of the heating element and the speed of the fan in real time, the problem of existing equipment being unable to independently control the air outlet effect is solved, achieving more flexible heating needs and improved comfort.

CN122305531APending Publication Date: 2026-06-30GD MIDEA ENVIRONMENT APPLIANCES MFG

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
GD MIDEA ENVIRONMENT APPLIANCES MFG
Filing Date
2024-12-27
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing skirting board heating devices cannot flexibly meet users' heating needs and cannot independently control the airflow effect of each air outlet, resulting in reduced user comfort.

Method used

By setting multiple air outlets in the heating equipment and using temperature sensors to collect indoor temperature parameters and air outlet height parameters in real time, the power of the heating element and the speed of the fan assembly can be controlled separately to achieve independent control of each air outlet.

Benefits of technology

It enables flexible control of air outlets with different height parameters, meeting users' personalized heating needs and improving user comfort.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This application provides a control method, apparatus, heating device, and storage medium for a heating device. The method is applied to the control component of the heating device, which includes a temperature sensor, multiple air outlets, at least one heating element, and a fan assembly. The air outlets are arranged vertically. The heating element and temperature sensor are connected to the control component. The method includes: acquiring indoor temperature parameters of the space where the heating device is located, collected by the temperature sensor; determining the power parameters of the heating element and the rotational speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlets; controlling the operation of the heating element based on the power parameters; and controlling the operation of the fan assembly based on the rotational speed parameters. This method enables independent control of the airflow effect of each air outlet, allowing for more flexible fulfillment of users' heating needs.
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Description

Technical Field

[0001] This application relates to the field of household appliances, and more specifically, to control methods, apparatus, heating devices, and storage media for heating equipment in the field of household appliances. Background Technology

[0002] With the continuous improvement of living standards, heating equipment has been widely used. For baseboard heating equipment, convection is usually used for heating. Adding a fan to the relevant technology helps the heating equipment to deliver hot air to the indoor space, but it can only control the overall air output effect and cannot flexibly meet the user's heating needs, thus reducing the comfort of using the heating equipment. Summary of the Invention

[0003] This application provides a control method, device, heating device, and storage medium for a heating device. The method enables independent control of the air outlet effect of each air outlet, which can more flexibly meet the user's heating needs.

[0004] In a first aspect, a control method for a heating device is provided, applied to a control component of the heating device. The heating device includes a temperature sensor, multiple air outlets, at least one heating element, and a fan assembly. The air outlets of the heating device are arranged vertically. The heating element and the temperature sensor are respectively connected to the control component. The method includes:

[0005] Acquire indoor temperature parameters of the space where the heating device is located, collected by a temperature sensor;

[0006] The power parameters of the heating element and the rotational speed parameters of the fan assembly are determined based on the indoor temperature parameters and the height parameters of the air outlet.

[0007] Controlling the operation of the heating element based on its power parameters;

[0008] The operation of the fan components is controlled based on the rotational speed parameters of the fan components.

[0009] Secondly, a control device for a heating device is provided, applied to the heating device, which includes a temperature sensor, multiple air outlets, at least one heating element, and a fan assembly. The air outlets of the heating device are arranged vertically. The heating element and temperature sensor are respectively connected to the device. The device includes:

[0010] The acquisition unit is used to acquire the indoor temperature parameters of the space where the heating device is located, collected by the temperature sensor.

[0011] The determining unit is used to determine the power parameters of the heating element and the speed parameters of the fan assembly based on the indoor temperature parameters;

[0012] The first control unit is used to control the operation of the heating element based on the power parameters corresponding to the heating element.

[0013] The second control unit is used to control the operation of the wind turbine components based on the speed parameters corresponding to the wind turbine components.

[0014] Thirdly, a control device for a heating device is provided, applied to the heating device, the heating device including a temperature sensor, multiple air outlets, a parameter selection interface, at least one heating element and a fan assembly, wherein each of the air outlets of the heating device is arranged vertically, and the heating element, the temperature sensor, and the parameter selection interface are respectively connected to the device, the device comprising:

[0015] The parameter acquisition unit is used to acquire the sixth power parameter for the heating element and the sixth speed parameter for the fan assembly based on the parameter selection interface.

[0016] A heating control unit is used to control the operation of the heating element based on a sixth power parameter of the heating element;

[0017] A speed control unit is used to control the operation of the fan assembly based on a sixth speed parameter of the fan assembly.

[0018] Fourthly, a heating device is provided, comprising: a memory for storing executable program code; and a control component for calling and running the executable program code from the memory, causing the heating device to perform the method described in the first aspect or any possible implementation thereof.

[0019] Fifthly, a computer program product is provided, comprising: computer program code, which, when run on a computer, causes the computer to perform the methods described in the first aspect or any possible implementation thereof.

[0020] In a sixth aspect, a computer-readable storage medium is provided that stores computer program code, which, when executed on a computer, causes the computer to perform the methods described in the first aspect or any possible implementation thereof.

[0021] In this embodiment, the rotation speed of at least one fan component and the power of at least one heating element of the heating device are determined by real-time collected indoor temperature parameters and air outlet height parameters. This achieves that the overall air outlet effect of the heating device meets the comfort requirements corresponding to the indoor temperature parameters, while also enabling independent control of the air outlet effect of air outlets with different height parameters, thus more flexibly meeting the user's heating needs. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the structure of a heating device provided in an embodiment of this application;

[0023] Figure 2 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0024] Figure 3 This is a schematic flowchart of a control method for a heating device provided in an embodiment of this application;

[0025] Figure 4 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0026] Figure 5 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0027] Figure 6 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0028] Figure 7 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0029] Figure 8 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0030] Figure 9 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0031] Figure 10 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application.

[0032] Figure 11 This is a schematic flowchart of a control method for a heating device provided in an embodiment of this application;

[0033] Figure 12 This is a schematic diagram of the structure of a control device for a heating device provided in an embodiment of this application;

[0034] Figure 13 This is a schematic diagram of the structure of a control device for a heating device provided in an embodiment of this application;

[0035] Figure 14 This is a schematic diagram of the structure of a heating device provided in an embodiment of this application. Detailed Implementation

[0036] The technical solutions in this application will be clearly and thoroughly described below with reference to the accompanying drawings. In the description of the embodiments of this application, unless otherwise stated, " / " means "or," for example, A / B can mean A or B. "And / or" in the text is merely a description of the relationship between related objects, indicating that three relationships can exist. For example, A and / or B can represent: A existing alone, A and B existing simultaneously, and B existing alone. Furthermore, in the description of the embodiments of this application, "multiple" refers to two or more than two.

[0037] Hereinafter, the terms "first" and "second" are used for descriptive purposes only and should not be construed as implying or suggesting relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature.

[0038] Please see Figure 1 , Figure 1 This is a schematic diagram of the heating device provided in an embodiment of this application. The heating device 001 includes a housing, multiple air outlets 11, a temperature sensor, a fan assembly 21, and a heating element 31. A receiving cavity is formed inside the housing, and the fan assembly 21, heating element 31, and control assembly are disposed within the receiving cavity of the heating device. The air outlets 11 are disposed on the first side wall of the housing. Figure 1 The housing of the heating device 001 shown may include six sidewalls. The first sidewall where the air outlet 11 is located can be determined according to actual needs, and multiple air outlets 11 are arranged vertically on the first sidewall. It is understood that the housing structure of the heating device 001 is not limited to... Figure 1 The structure shown can be customized according to actual needs.

[0039] The heating device includes at least one fan assembly 21 and at least one heating element 31, with the fan assembly and heating element assembly corresponding to air outlets. Specifically, when the heating device includes one fan assembly 21 and one heating element 31, the fan assembly 21 and the heating element 31 are aligned with multiple air outlets, allowing the heat generated by the fan assembly 21 and the heating element 31 to be discharged through multiple air outlets 11. When the heating device includes multiple fan assemblies 21 and / or multiple heating elements 31, the multiple fan assemblies 21 and / or multiple heating elements 31 are aligned with each air outlet, i.e., there is a one-to-one or one-to-many relationship between the fan assembly and the air outlet; similarly, there is also a one-to-one or one-to-many relationship between the heating element assembly and the air outlet.

[0040] The control component is connected to the fan assembly 21, the heating element 31, and the temperature sensor respectively. It is used to adjust the power parameters of the heating element 31 and the speed parameters of the fan assembly 21 based on the indoor temperature parameters of the space where the heating equipment is located and the height parameters of the air outlet collected by the temperature sensor, so as to control the heat energy delivered from the air outlet 11.

[0041] The heating element 31 can be disposed between the fan assembly 21 and the air outlet 11. In another embodiment, the fan assembly 21 can also be disposed between the heating element 31 and the air outlet 11. The heating element 31 is used to provide heat energy, and the fan assembly 21 is used to discharge the heat energy provided by the heating element 31 through the air outlet 11. The fan assembly 21 is a cross-flow fan, and the air outlet 11 is an elongated shape adapted to the cross-flow fan. Other types of fans, such as a DC fan, can also be selected for the fan assembly 21.

[0042] The heating device 001 may also include physical control buttons, a touch screen, etc. The start-up, temperature adjustment and other control logic of the heating device 001 can be controlled by the physical control buttons or the virtual buttons on the touch screen.

[0043] The heating device 001 may also include a network module, which can provide wireless network services or wired network services, such as wireless local area networks (WLAN), local area networks (LAN), cellular networks, 2G networks, 3G networks, 4G networks, 5G networks, etc. When the network module is connected to the network, users can control the heating device to turn it on, off, or adjust the temperature using devices such as mobile phones and tablets, thereby achieving remote control of the heating device 001.

[0044] It should be noted that, Figure 1 The schematic diagram of the heating device shown is merely an example. The schematic diagram of the heating device described in this application is for the purpose of more clearly illustrating the technical solution of this application embodiment and does not constitute a limitation on the technical solution provided in this application embodiment. As those skilled in the art will know, with the evolution of heating devices, the technical solution provided in this application embodiment is also applicable to similar technical problems.

[0045] based on Figure 1 The heating device shown in the diagram typically employs a single air outlet design in existing technologies. Please refer to [link / reference needed]. Figure 2 , Figure 2 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 2As shown, the heating device 001 has an air outlet 11a, a fan assembly 21a, and a heating element 31a. The fan assembly 21a is used to discharge the heat energy provided by the heating element 31a through the air outlet 11a. Since there is only one air outlet 11a, one fan assembly 21a, and one heating element 31a, the air blown out of the air outlet 11a has uniform heat and uniform wind speed. However, in some cases, Figure 2 The heating device 001 shown does not provide a good user experience by supporting overall body heating. For example, if a user stands in front of the air outlet 11a and the airflow from the outlet 11a towards the user's upper body, especially the head, is too strong or too hot, it may cause the user to feel uncomfortable. Figure 2 The heating device 001 shown has only one air outlet 11a, one fan assembly 21a, and one heating element 31a. This structural limitation leads to... Figure 2 The heating device 001 shown cannot provide zoned heating for the user's body. Clearly, Figure 2 The heating device 001 shown has only one air outlet 11a, one fan assembly 21a, and one heating element 31a. This structural limitation leads to... Figure 2 The heating device 001 shown cannot provide users with comfortable heating.

[0046] Therefore, the heating device provided in this application embodiment has multiple air outlets, which are arranged vertically. The correspondence between the air outlets, the fan assembly, and the heating element is determined by the height parameters of the three components within the heating device. For example, the lowest and highest points of a certain air outlet define its height parameter as [y11, y12], the lowest and highest points of a certain fan assembly define its height parameter as [y21, y22], and the lowest and highest points of a certain heating element define its height parameter as [y31, y32]. If [y11, y12] overlaps with [y21, y22], then the air outlet corresponds to the fan assembly; if [y11, y12] overlaps with [y31, y32], then the air outlet corresponds to the heating element. Similarly, if [y11,y12] and [y21,y22] do not overlap, then there is no correspondence between the air outlet and the fan assembly; if [y11,y12] and [y31,y32] do not overlap, then there is no correspondence between the air outlet and the heating element.

[0047] Please refer to Figure 3 This is a flowchart illustrating a control method for a heating device provided in an embodiment of this application. Figure 3 As shown, the method in this application embodiment may include the following steps S101-S104.

[0048] S101, acquire the indoor temperature parameters of the space where the heating device is located, collected by the temperature sensor;

[0049] S102, determine the power parameters of the heating element and the rotation speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlet;

[0050] Specifically, the indoor temperature parameter refers to the temperature value of the space where the heating equipment is located; the power parameter refers to the heating power of the heating element during operation; the unit of the power parameter can be watts (W), which represents the rate at which energy is converted, used, or dissipated per unit time. Other units for the power parameter are not listed here. The speed parameter refers to the rotational speed of the fan assembly during operation; the unit of the speed parameter can be revolutions per second (r / s or R / S), representing the number of times the blades rotate per second; or the unit of the speed parameter can be revolutions per minute (r / min or RPM), representing the number of times the blades rotate per minute.

[0051] In one embodiment, the rotational speed and power parameters of each fan component corresponding to different indoor temperature parameters can be pre-stored in the heating device. Therefore, when the indoor temperature parameter is acquired by the temperature sensor, the corresponding rotational speed and power parameters can be determined. Since the rotational speed and power parameters are determined based on the indoor temperature parameter, it ensures that the overall airflow effect of the heating device is related to the actual acquired indoor temperature parameter.

[0052] In one embodiment, when there are multiple fan assemblies and one heating element, each fan assembly corresponds one-to-one with the air outlet of the heating device. The rotation speed parameters of each fan assembly corresponding to the air outlet with different indoor temperature parameters and the power parameters of the heating element corresponding to each indoor temperature parameter can be pre-stored. Since the rotation speed of the fan assembly can adjust the airflow, and the different rotation speed parameters of the fan assemblies corresponding to different air outlets can control the different air outlet speeds, for example, controlling the air outlet speed of some air outlets to be higher and the air outlet speed of other air outlets to be lower.

[0053] In another embodiment, when there are multiple heating elements and one fan, each heating element is matched with an air outlet of the heating device. Similarly, the power parameters of the heating elements corresponding to different height parameters of the air outlets at each indoor temperature parameter and the rotation speed parameters of the fan assembly corresponding to each indoor temperature parameter can be pre-stored. Since the heat generated by the heating elements varies under different power parameters, even when there is only one fan assembly corresponding to each air outlet, the different power parameters of the heating elements corresponding to each air outlet can control the different air temperatures delivered to the space where the heating device is located from each air outlet. For example, the heating element with higher power parameters delivers a higher air temperature.

[0054] In other embodiments, where each air outlet corresponds to a heating element and a fan, i.e., the heating element and the fan are respectively one-to-one with the air outlet, similarly, the rotation speed parameters of the fan assembly and the power parameters of the heating element of the air outlet corresponding to the height parameter can be stored for each indoor temperature parameter. Specifically, it is possible to store that the power parameters of the heating element are the same but the rotation speed parameters of the fan assembly are different for air outlets corresponding to different height parameters, or that the power parameters of the heating element and the rotation speed parameters of the fan assembly are different for air outlets corresponding to different height parameters, or that both the rotation speed parameters of the fan assembly and the power parameters of the heating element are different for air outlets corresponding to different height parameters, thereby controlling the different warm air delivery effects from different air outlets to the space where the heating equipment is located.

[0055] S103, controls the operation of the heating element based on the power parameters of the heating element;

[0056] S104 controls the operation of the fan assembly based on the speed parameters of the fan assembly.

[0057] In one embodiment, after obtaining the power parameters of the heating element and the rotation speed parameters of the fan assembly, the operation of at least one heating element can be controlled according to the obtained power parameters, and the operation of at least one fan assembly can be controlled according to the obtained rotation speed parameters. This allows control over the air outlet effects of each air outlet of the heating device, including consistent air outlet temperature, inconsistent air speed, different air outlet temperature, and the same air speed, or different air speed and air outlet temperature.

[0058] In this embodiment, the rotation speed of at least one fan component and the power of at least one heating element of the heating device are determined by real-time collected indoor temperature parameters and air outlet height parameters. This achieves that the overall air outlet effect of the heating device meets the comfort requirements corresponding to the indoor temperature parameters, while also enabling independent control of the air outlet effect of air outlets with different height parameters, thus more flexibly meeting the user's heating needs.

[0059] Please refer to Figure 4 , Figure 4 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 4 As shown, heating device 001 employs a configuration with multiple air outlets, multiple fan assemblies, and a single heating element. Among these, in... Figure 4The first air outlet includes multiple first air outlets, namely first air outlet 11b, first air outlet 12b, and first air outlet 13b; multiple first fan assemblies, namely first fan assembly 21b, first fan assembly 22b, and first fan assembly 23b; each first air outlet corresponds to a first fan (for example, first air outlet 11b corresponds to first fan assembly 21b), and first air outlet 11b, first air outlet 12b, and first air outlet 13b correspond to a first heating element 31b. In other words, even when there is only one first heating element 31b, the different airflow effects of each air outlet can be controlled by the rotation speed parameters of each first fan component. The height parameters of the first air outlet 11b are [y11, y12], the height parameters of the first air outlet 12b are [y13, y14], and the height parameters of the first air outlet 13b are [y15, y16], where y11 > y12 > y13 > y14 > y15 > y16.

[0060] Specifically, after the heating device collects the indoor temperature parameters of the space where the heating device is located through a temperature sensor, it determines the first power parameter of the first heating element and the first rotation speed parameter of the first fan assembly corresponding to the first air outlet with different height parameters under the same indoor temperature parameters. The correlation between the first rotation speed parameters of the first fan assembly corresponding to the air outlet with different height parameters under different indoor temperature parameters and the first power parameter of the first heating element corresponding to different indoor temperature parameters can be pre-stored. Therefore, after the indoor temperature parameters are collected by the temperature sensor, the first power parameter corresponding to that indoor temperature parameter and the first rotation speed parameter of the first fan assembly corresponding to the first air outlet with different height parameters can be determined through the correlation.

[0061] For example, in the embodiments of this application, the heating element has three power options: 2000W, 1000W, and 500W. For the DC fan type fan assembly, it has three power options: 400r / min, 800r / min, and 1200r / min. When the indoor temperature is 15℃, the first power parameter of the first heating element 31b corresponding to the indoor temperature parameter is determined to be 1000W based on the pre-stored association relationship. The first speed parameter of the first fan assembly 21b corresponding to the first air outlet 11b with height parameters [y11, y12] is determined to be 400r / min. The first speed parameter of the first fan assembly 22b corresponding to the first air outlet 12b with height parameters [y13, y14] is determined to be 800r / min. The first speed parameter of the first fan assembly 23b corresponding to the first air outlet 13b with height parameters [y15, y16] is determined to be 1200r / min.

[0062] In this embodiment of the application, when the heating device has only one heating element, the rotation speed of the fan assembly corresponding to each first air outlet is determined by controlling the height parameter of the air outlet. This achieves the control of different amounts of warm air delivered by the first air outlets with different height parameters. Furthermore, by controlling the first fan assembly corresponding to the first air outlet with a larger height parameter to operate at a smaller speed, it avoids the higher air outlets from outputting too much heat, causing heat to flow to higher places.

[0063] Further, please refer to Figure 5 , Figure 5 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 5 As shown, heating device 001 employs multiple air outlets, each with a corresponding fan assembly, and multiple air outlets corresponding to one heating element. It also combines this with a separate configuration where each air outlet is paired with a heating element. Among these... Figure 5 The air outlets include multiple air outlets, including second air outlet 11c, second air outlet 12c, and second air outlet 13c. Each second air outlet corresponds to a second fan assembly (e.g., second air outlet 11c corresponds to second fan assembly 21c, and second air outlet 12c corresponds to second fan assembly 22c). Each of the multiple second air outlets (second air outlet 11c, second air outlet 12c) corresponds to a second heating element 31c. Furthermore, the heating device also includes a second heating element 32c corresponding to second air outlet 13c, and a second fan assembly 23c corresponding to second air outlet 13c.

[0064] In this case, the heating equipment controls the second fan assembly (21c, 22c) and the second heating element (31c) in the same way as described above. Figure 4 The control methods for the first fan assembly and the first heating element are similar and will not be repeated here. The control method for the second fan assembly 23c and the second heating element 32c in the heating equipment can be as follows: the second rotational speed parameter of each second fan assembly is determined based on the indoor temperature parameter and the height parameter of the air outlet, and the second power parameter of each second heating element is determined based on the indoor temperature parameter and the height parameter of the air outlet. The second rotational speed parameter of each second fan assembly and the second power parameter of each second heating element corresponding to the indoor temperature parameter and the height parameter of the air outlet are also preset. Therefore, when the indoor temperature parameter is collected by the temperature sensor, the second rotational speed parameter of each second fan assembly and the second power parameter of each second heating element corresponding to the indoor temperature parameter and the air outlet can be determined. It is understood that... Figure 5The example given is that there is only one second air outlet. In this embodiment, there may be multiple second air outlets, and the second heating element and the second fan assembly are respectively set to correspond to the second air outlet.

[0065] For example, based on the above control of the heating element and fan assembly when multiple air outlets correspond to one heating element, the following description will explain a second fan assembly corresponding to each air outlet and a second heating element corresponding to each second air outlet. For example, the height parameter of the second air outlet 13c is [y17, y18]. When the indoor temperature parameter is 15°C, the second rotation speed parameter of the second fan assembly 32c corresponding to the indoor temperature parameter of 15°C and the height parameter of [y17, y18] is determined to be 1200 r / min, and the second power parameter of the second heating element 23c is determined to be 2000 W. That is, in this embodiment of the application, when multiple second heating components are provided, by controlling the power parameter of the second heating element corresponding to the second air outlet with different height parameters to be different, the air outlet temperature of the second air outlet with different height parameters is controlled to be different, thereby realizing the control of the warm air temperature of the air outlet.

[0066] In this embodiment, when the air outlet includes a first air outlet, each first air outlet corresponds to a first fan assembly, and multiple first air outlets correspond to a first heating element, the first rotation speed parameter of each first fan assembly is determined based on indoor temperature parameters and height parameters. This allows control of the first rotation speed parameter of the first fan assembly corresponding to different air outlets, thereby achieving control of the air outlet speed of different air outlets. Based on this, a second fan assembly and a second heating element are set corresponding to each second air outlet. Then, the second rotation speed parameter of the second fan assembly and the second power parameter of the second heating element are determined based on indoor temperature parameters and height parameters, respectively. This enables control of the air outlet speed and air outlet temperature of different air outlets, thereby achieving control of the local air outlet effect of the heating equipment.

[0067] Please refer to Figure 6 , Figure 6 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 6 As shown, heating device 001 employs a configuration with multiple air outlets, a single fan assembly, and multiple heating elements. Among these... Figure 6The air outlets include third air outlet 11d, third air outlet 12d, and third air outlet 13d; multiple third heating elements, namely third heating element 31d, third heating element 32d, and third heating element 33d; each third air outlet corresponds to a third heating element (e.g., third air outlet 11d corresponds to third heating element 31d), and third air outlets 11d, 12d, and 13d correspond to a third fan assembly 21d. That is, even when there is only one third fan assembly 21d, by controlling the power parameters of the third heating element corresponding to each third air outlet, the airflow efficiency of each air outlet can be controlled by the power parameters of each third heating element.

[0068] Specifically, after the heating device collects the indoor temperature parameters of the space where the heating device is located through a temperature sensor, it determines the third power parameters of each third heating element based on the indoor temperature parameters and the height parameters of the third air outlet, and determines the third rotation speed parameters of the third fan assembly based on the indoor temperature parameters. The third rotation speed parameters of the third fan assembly corresponding to different indoor temperature parameters, and the correlation between the third power parameters of each third heating element corresponding to different height parameters of the third air outlet at each indoor temperature parameter, can be pre-stored. Therefore, after collecting the indoor temperature parameters through the temperature sensor, the third rotation speed parameters of the third fan assembly corresponding to that indoor temperature parameter, and the third power parameters of each third heating element corresponding to the height parameters of the third air outlet at that indoor temperature, can be determined through the correlation.

[0069] For example, in the embodiments of this application, the heating element has three power options: 2000W, 1000W, and 500W. For the DC fan type fan assembly, it has three power options: 400r / min, 800r / min, and 1200r / min. When the indoor temperature is 15℃, based on the pre-stored correlation, the third rotational speed parameter of the third fan component 21d corresponding to this indoor temperature parameter is determined to be 1200r / min. The third power parameter of the third heating element 31d corresponding to the third air outlet 11d with height parameters [y11, y12] is determined to be 500W. The third power parameter of the third heating element 32d corresponding to the third air outlet 12d with height parameters [y13, y14] is determined to be 1000W. The third power parameter of the third heating element 33d corresponding to the third air outlet 13d with height parameters [y15, y16] is determined to be 2000W.

[0070] In this embodiment of the application, when the heating device has only one third fan component, the third power parameter of the third heating element corresponding to each air outlet is determined to be different by controlling the height parameter of the air outlet. This achieves the control of the temperature of the warm air delivered by the third air outlet with different height parameters to be different. Furthermore, by controlling the third power parameter of the air outlet with a larger height parameter to be smaller, the high temperature of the warm air output by the air outlet at a higher position is avoided, so as not to make the user feel scorched.

[0071] Further, please refer to Figure 7 , Figure 7 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 7 As shown, heating device 001 employs multiple air outlets, each with a corresponding heating element, and multiple air outlets corresponding to one fan assembly. It also combines this with a separate fan assembly for each air outlet. Among these... Figure 7 The heating device includes multiple air outlets, namely fourth air outlet 11e, fourth air outlet 12e, and fourth air outlet 13e. Each fourth air outlet corresponds to a fourth heating element (for example, fourth air outlet 11e corresponds to fourth heating element 31e, and fourth air outlet 12e corresponds to fourth heating element 32e). Each of the multiple fourth air outlets (fourth air outlet 11e, fourth air outlet 12e) corresponds to a fourth fan assembly 21e. Furthermore, the heating device also includes a fourth heating element 33e corresponding to fourth air outlet 13e, and a fourth fan assembly 22e corresponding to fourth air outlet 13e.

[0072] In this case, the control method of the heating equipment for the fourth fan assembly (21e) and the fourth heating element (31e, 32e) is the same as described above. Figure 6 The control methods for the third fan assembly (21d) and the third heating element (31d, 32d) are similar and will not be repeated here. The control method for the fourth fan assembly and the fourth heating element in the heating equipment can be as follows: The fourth rotational speed parameter of each of the fourth fan assemblies is determined based on the indoor temperature parameter and the height parameter of the air outlet; the fourth power parameter of each of the fourth heating elements is determined based on the indoor temperature parameter and the height parameter of the air outlet. The fourth rotational speed parameter of each of the fourth fan assemblies and the fourth power parameter of each of the fourth heating elements corresponding to the indoor temperature parameter and the height parameter of the air outlet are also preset. Therefore, when the indoor temperature parameter is collected by the temperature sensor, the fourth rotational speed parameter of each of the fourth fan assemblies and the fourth power parameter of each of the fourth heating elements corresponding to that indoor temperature parameter can be determined. It is understood that... Figure 7 The example given is that there is only one fourth air outlet. In this embodiment, there may be multiple fourth air outlets, and the fourth heating element and the fourth fan assembly are respectively set to correspond to the fourth air outlet.

[0073] For example, based on the above control of the heating element and the fan assembly when multiple air outlets correspond to a fan assembly, this section describes a fourth fan assembly corresponding to each air outlet and a second heating element corresponding to each fourth air outlet. For example, the height parameter of the fourth air outlet 13e is [y17, y18]. When the indoor temperature parameter is 15°C, the fourth rotation speed parameter of the fourth fan assembly 32e corresponding to the indoor temperature parameter of 15°C and the height parameter of [y17, y18] is determined to be 1200 r / min, and the fourth power parameter of the fourth heating element 23e is determined to be 2000 W. That is, in this embodiment of the application, when multiple fourth heating components are provided, by controlling the power parameter of the fourth heating element corresponding to the fourth air outlet with different height parameters to be different, the outlet air temperature of the fourth air outlet with different height parameters is controlled to be different, thereby realizing the control of the warm air temperature of the air outlet.

[0074] In this embodiment, when the air outlet includes a third air outlet, each third air outlet corresponds to a third heating element, and multiple third air outlets correspond to a third fan assembly, the third power parameter of each third heating element corresponding to the third air outlet is determined based on the indoor temperature parameter and the height parameter of the third air outlet. This allows control of the third power parameter of the third heating element corresponding to different air outlets, thereby achieving control of the air outlet temperature of different air outlets. Based on this, a fourth fan assembly and a fourth heating element are set respectively corresponding to each fourth air outlet. Then, based on the indoor temperature parameter and the height parameter of the fourth air outlet, the fourth speed parameter of the fourth fan assembly and the fourth power parameter of the fourth heating element are determined respectively, thereby achieving control of the air outlet speed and air outlet temperature of different air outlets, and achieving control of the local air outlet effect of the heating equipment.

[0075] Please refer to Figure 8 , Figure 8 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 8 As shown, heating device 001 employs multiple air outlets, a heating element corresponding to each air outlet, and a fan assembly corresponding to each air outlet. Among these... Figure 8 The air outlets include multiple outlets, namely the fifth air outlet 11f, the fifth air outlet 12f, and the fifth air outlet 13f. Each fifth air outlet corresponds to a fifth heating element (the fifth air outlet 11f corresponds to the fifth heating element 31f, the fifth air outlet 12f corresponds to the fifth heating element 32f, and the fifth air outlet 13f corresponds to the fifth heating element 33f). Each fifth air outlet also corresponds to a fifth fan assembly (the fifth air outlet 11f corresponds to the fifth fan assembly 21f, the fifth air outlet 12f corresponds to the fifth fan assembly 22f, and the fifth air outlet 13f corresponds to the fifth fan assembly 23f).

[0076] Specifically, in this embodiment, the control of the fifth fan assembly and the fifth heating element corresponding to each fifth air outlet can also be achieved by pre-storing the correlation between the fifth rotation speed parameters of each fifth fan assembly and the fifth power parameters of each fifth heating element corresponding to different indoor temperature parameters and fifth air outlet height parameters. Thus, after the indoor temperature parameters are collected by the temperature sensor, the fifth rotation speed parameters of each fifth fan assembly and the fifth power parameters of each fifth heating element corresponding to the indoor temperature parameters and fifth air outlet height parameters can be determined through the correlation. By controlling the fifth rotation speed parameters of the fifth fan assembly corresponding to the height parameters of each fifth air outlet and the fifth power parameters of the fifth heating element corresponding to the height parameters of each fifth air outlet, the operation of each fifth fan assembly and each fifth heating element is controlled, resulting in different air outlet temperatures and air speeds at different air outlets, thereby achieving different air outlet effects.

[0077] Further, please refer to Figure 9 , Figure 9 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 9 As shown, the heating device 001 employs multiple air outlets, namely the sixth air outlet 11g, the sixth air outlet 12g, the sixth air outlet 13g, and the sixth air outlet 14g; multiple sixth fan assemblies, namely the sixth fan assembly 21g, the sixth fan assembly 22g, and the sixth fan assembly 23g; and multiple sixth heating elements, namely the sixth heating element 31g, the sixth heating element 32g, and the sixth heating element 33g. In this embodiment of the heating device, there are two ways to arrange the air outlets, fan assemblies, and heating elements. One is that each sixth air outlet corresponds to a sixth fan assembly (e.g., the sixth air outlet 11g). g corresponds to the sixth fan assembly 21g, and the sixth air outlet 12g corresponds to the sixth fan assembly 22g. Multiple sixth air outlets correspond to a sixth heating element (e.g., the sixth air outlet 11g and the sixth air outlet 12g correspond to the same sixth heating element 31). Another configuration is that each sixth air outlet corresponds to a sixth heating element (e.g., the sixth air outlet 13g corresponds to the sixth heating element 32g, and the sixth air outlet 14g corresponds to the sixth heating element 33g), and multiple sixth air outlets correspond to a sixth fan assembly (e.g., the sixth air outlet 13g and the sixth air outlet 14g correspond to the sixth fan assembly 23g).

[0078] In this embodiment, the rotation speed parameters of the sixth fan component and the power parameters of the sixth heating element corresponding to the currently collected indoor temperature parameters can also be determined based on the pre-stored correlation between the rotation speed parameters of each sixth fan component and the power parameters of each sixth heating element corresponding to different indoor temperature parameters. This will not be elaborated further here.

[0079] In the embodiments of this application, each air outlet of the heating device corresponds to a different fan assembly and heating assembly, thereby enabling the air outlet temperature and air outlet speed of each air outlet to be controlled separately, thus achieving control of the local air outlet effect of the heating device.

[0080] Furthermore, please continue to refer to Figure 2 During the temperature adjustment process of the heating equipment, due to thermal buoyancy, when warm air is discharged from the air outlet 11a, it will rise upon contact with the surrounding cooler, denser air. In other words, for... Figure 2 The heating device 001 shown has a tendency for most of the heat to rise due to thermal buoyancy, resulting in uneven temperature distribution. This unevenness is particularly noticeable near the heating device 001. For example, if a user stands in front of the air outlet 11a and the airflow from the outlet 11a towards the user's upper body, especially the head, is too strong or too hot, it may cause the user to feel uncomfortable.

[0081] Based on this, in this embodiment, for two adjacent air outlets, the heat flow of the air outlet at the first position is less than or equal to the heat flow of the air outlet at the second position, where the first position is higher than the second position. Heat flow represents the amount of heat transferred through a certain area per unit time, typically expressed in watts (W). It is understood that, with the power parameters of the heating element remaining constant, a higher rotational speed means that the fan assembly blades can push more air per unit time, thus generating a greater heat flow; conversely, with the fan assembly rotational speed parameters remaining constant, higher power means that the heating element heats to a higher temperature per unit time, thus generating a greater heat flow. Therefore, the heat flow of each air outlet can be controlled by controlling the power parameters of the heating element corresponding to each air outlet and / or the rotational speed parameters of the fan assembly.

[0082] by Figure 8 For example, in heating device 001, the power parameters of the heating elements corresponding to each air outlet are the same. Air outlet 11f corresponds to fan assembly 21f, air outlet 12f corresponds to fan assembly 22f, and air outlet 13f corresponds to fan assembly 23f. Among them, fan assembly 21f and fan assembly 22f are two adjacent fan assemblies, fan assembly 22f and fan assembly 23f are two adjacent fan assemblies, fan assembly 21f is the tallest fan assembly in the vertical direction, and fan assembly 23f is the shortest fan assembly in the vertical direction.

[0083] Assume the rotational speed of fan assembly 21f is x1 rpm, the rotational speed of fan assembly 22f is x2 rpm, and the rotational speed of fan assembly 23f is x3 rpm. To ensure that the heat flow at the outlet at the first position is less than or equal to the heat flow at the outlet at the second position, the rotational speed parameters can be one of the following three cases:

[0084] In one case, x1 < x2 and x2 < x3;

[0085] In one case, x1 ≤ x2 and x2 ≤ x3;

[0086] In one case, x1 ≤ x2 and x2 < x3.

[0087] Similarly, in the embodiments of this application, when the fan speeds corresponding to each air outlet are the same, the heat flow rate of the air outlet located at the first position can be less than or equal to the heat flow rate of the air outlet located at the second position by adjusting the power parameters of the corresponding heating element, which will not be elaborated here.

[0088] In this embodiment of the application, by controlling the heat flow of the air outlet located at a higher position to be less than or equal to the heat flow of the air outlet located at a lower position, the problem of overheating of the user's head due to buoyancy and the large heat flow output of the air outlet at a higher position can be avoided, effectively meeting the user's usage needs.

[0089] Please refer to Figure 10 , Figure 10 This is a schematic diagram illustrating an example of how an air outlet and corresponding components are arranged, as provided in an embodiment of this application. Figure 10 As shown, the heating equipment also includes a partition, which is set in accordance with the air outlet.

[0090] Furthermore, in this embodiment, the opening parameters of the baffles corresponding to each air outlet are determined based on the indoor temperature parameters, and then each baffle is activated according to the opening parameters. The heat flow of each air outlet is controlled by controlling the opening parameters of the baffles.

[0091] Specifically, in this embodiment of the application, after obtaining the indoor temperature parameters, the temperature range corresponding to the indoor temperature parameters can be further determined, and the opening threshold of the baffle corresponding to the air outlet in the temperature range can be determined as the opening parameter of each baffle.

[0092] Please see the table below for further details:

[0093]

[0094] Figure 10 Each baffle in the system controls the size of each air outlet. The larger the opening parameter, the larger the outlet, and the greater the heat flow through that outlet per unit time. Figure 10 In a heating device, if each air outlet corresponds to the same heating element and the same fan assembly, the heat output of each air outlet can be controlled by adjusting the opening parameters of the baffles corresponding to each air outlet.

[0095] Similarly, in this application, when multiple air outlets correspond to the same fan assembly, and each air outlet corresponds to a partition and a heating element, the power parameters of the heating element and / or the opening parameters of the partition can be controlled to control the different heat flow rates output by the air outlets. Likewise, when multiple air outlets correspond to the same fan assembly, and each air outlet corresponds to a partition, the rotation speed parameters of the fan assembly and / or the opening parameters of the partition can be controlled to control the different heat flow rates output by the air outlets. The components corresponding to the air outlets in the heating equipment can be arranged in various ways. In the embodiments of this application, any one or more of the opening parameters of the partition, the rotation speed parameters of the fan assembly, and the power parameters of the heating element can be controlled to control the different heat flow rates of the air outlets, thereby achieving local control of the air output effect of each air outlet of the heating equipment.

[0096] Furthermore, in order to avoid the problem of excessive heat flow from the air outlet at a higher position of the heating device, which could lead to excessively high head temperature for the user, in this embodiment, when multiple air outlets correspond to the same heating element and air outlet assembly, the opening parameter of the partition located at the first position is not greater than the opening parameter of the partition located at the second position for any two adjacent partitions, with the first position being higher than the second position.

[0097] Please refer to Figure 11 , Figure 11 This is a flowchart illustrating a control method for a heating device provided in an embodiment of this application. The control method for the heating device includes steps S201-S203.

[0098] S201, based on the parameter selection interface, obtain the sixth power parameter for the heating element and the sixth speed parameter for the fan assembly;

[0099] S202, control the operation of the heating element based on the sixth power parameter of the heating element;

[0100] S203, control the operation of the fan assembly based on the sixth speed parameter of the fan assembly.

[0101] In one embodiment, the heating device includes a parameter selection interface connected to the control component. The parameter selection interface is used to obtain the power parameters of the heating element and the rotational speed parameters of the fan component.

[0102] In one embodiment, the parameter selection interface is a power parameter adjustment module and a speed parameter module on a touch screen. Users can input power parameters and speed parameters by dragging the sliders corresponding to the power parameter adjustment module and the speed parameter module, or by clicking the virtual buttons for power parameters and speed parameters.

[0103] In another embodiment, the parameter selection interface can also be a physical button, whereby the user can input the power parameters of the heating element and the rotational speed parameters of the fan assembly by pressing the "increase" button and "decrease" button corresponding to the heating element and fan assembly, respectively.

[0104] In this embodiment, the power parameters of the heating element and the rotation speed parameters of the fan assembly are received by the user through the parameter selection interface. The user can input the power parameters of the heating element and the rotation speed parameters of the fan assembly according to their own needs, so that the temperature of the space where the heating device works meets the individual needs and improves the user experience.

[0105] It should be emphasized that the embodiments and features described above are not limiting and can be used in combination with other embodiments and features of the present invention. This application involves multiple embodiments, and all features in each embodiment are not limited to the scenario described in a single embodiment without conflict. Features can be arbitrarily combined with each other, and multiple embodiments can also be arbitrarily combined. The combined solution is still within the protection scope of this application.

[0106] The following will be combined with the appendix Figure 12 , 13 This application provides a detailed description of the control device for the heating equipment provided in the embodiments. It should be noted that the appendix... Figure 12 , 13 The control device of the heating equipment in this manual is used to execute the functions described herein. Figure 3 , Figure 11 The methods shown in the embodiments are illustrated for ease of explanation, showing only the parts relevant to the embodiments of this application. For specific technical details not disclosed, please refer to this specification. Figure 3 , Figure 12 The example shown.

[0107] Please see Figure 12 The control device 1 for the heating equipment is applied to the heating equipment, which includes a temperature sensor, multiple air outlets, at least one heating element, and a fan assembly. The air outlets of the heating equipment are arranged vertically. The heating element and temperature sensor are respectively connected to the device. The device 1 includes:

[0108] The acquisition unit 11 is used to acquire the indoor temperature parameters of the space where the heating device is located, collected by the temperature sensor;

[0109] The determining unit 12 is used to determine the power parameters of the heating element and the rotation speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlet;

[0110] The first control unit 13 is used to control the operation of the heating element based on the power parameters corresponding to the heating element.

[0111] The second control unit 14 is used to control the operation of the wind turbine component based on the speed parameters corresponding to the wind turbine component.

[0112] Optionally, the fan assembly and the heating element are respectively associated with the air outlet.

[0113] Optionally, the air outlet of the heating device includes a first air outlet, each first air outlet corresponding to a first fan assembly, and multiple first air outlets corresponding to a first heating element.

[0114] Optionally, the determining unit 12 includes: a first determining subunit 121 and a second determining subunit 122.

[0115] The first determining subunit 121 is used to determine the first rotation speed parameter of each first fan component based on the indoor temperature parameter and the height parameter of the first air outlet.

[0116] The second determining subunit 122 is used to determine the first power parameter of the first heating element based on the indoor temperature parameter.

[0117] Optionally, the air outlet of the heating device may also include a second air outlet, each second air outlet corresponding to a second fan assembly and each second air outlet corresponding to a second heating element.

[0118] Optionally, the determining unit 12 includes: a third determining subunit 123 and a fourth determining subunit 124.

[0119] The third determining subunit 123 is used to determine the second rotation speed parameters of each second fan component based on the indoor temperature parameters and the height parameters of the first air outlet.

[0120] The fourth determining subunit 124 is used to determine the second power parameters of each second heating element based on the indoor temperature parameters and the height parameters of the first air outlet.

[0121] Optionally, the air outlet of the heating device may also include a third air outlet, with multiple third air outlets corresponding to a third fan assembly, and each third air outlet corresponding to a third heating element.

[0122] Optionally, the determining unit 12 includes: a fifth determining subunit 125 and a sixth subunit 126.

[0123] The fifth determining subunit 125 is used to determine the third rotational speed parameter of the third fan assembly based on the indoor temperature parameter;

[0124] The sixth determining subunit 126 is used to determine the third power parameters of each third heating element based on the indoor temperature parameters and the height parameters of the first air outlet.

[0125] Optionally, the air outlet of the heating device includes a fourth air outlet, each fourth air outlet corresponding to a fourth fan assembly, and each fourth air outlet corresponding to a fourth heating element.

[0126] Optionally, the determining unit 12 includes: a seventh determining subunit 127 and an eighth determining subunit 128.

[0127] The seventh determining subunit 127 is used to determine the fourth rotation speed parameters of each fourth fan component based on the indoor temperature parameters and the height parameters of the first air outlet.

[0128] The eighth determining subunit 128 is used to determine the fourth power parameter of each fourth heating element based on the indoor temperature parameter and the height parameter of the first air outlet.

[0129] Optionally, the air outlet of the heating device may also include a fifth air outlet, each fifth air outlet corresponding to a fifth fan assembly and each fifth air outlet corresponding to a fifth heating element.

[0130] Optionally, the determining unit 12 includes: a ninth determining subunit 129 and a tenth determining subunit 1210.

[0131] The ninth determining subunit 129 is used to determine the fifth rotational speed parameters of each fifth fan component based on the indoor temperature parameters;

[0132] The tenth determining subunit 1210 is used to determine the fifth power parameter of each fifth heating element based on the indoor temperature parameter.

[0133] Optionally, for any two adjacent air outlets of the heating device, the heat flow of the air outlet located at the first position is less than or equal to the heat flow of the air outlet located at the second position, and the first position is higher than the second position.

[0134] Optionally, the determining unit 12 may further include an opening degree determining subunit 1214 and a control subunit 1215.

[0135] The opening degree determination subunit 1214 is used to determine the opening degree parameters of the baffle corresponding to each air outlet based on the indoor temperature parameters.

[0136] Control subunit 1215 is used to control the start-up partition based on the opening parameters.

[0137] Optionally, for any two adjacent partitions of the heating device, the opening parameter of the partition located in the first position is not greater than the opening parameter of the partition located in the second position, and the first position is higher than the second position.

[0138] Please refer to Figure 13 , Figure 13 This is a schematic diagram of a control device for a heating device. The heating device includes a temperature sensor, multiple air outlets, a parameter selection interface, at least one heating element, and a fan assembly. The air outlets of the heating device are arranged vertically. The heating element, temperature sensor, and parameter selection interface are connected to the device. Device 2 includes:

[0139] The parameter acquisition unit 21 is used to acquire the sixth power parameter for the heating element and the sixth speed parameter for the fan assembly based on the parameter selection interface.

[0140] Heating control unit 22 is used to control the operation of the heating element based on the sixth power parameter of the heating element;

[0141] Speed ​​control unit 23 is used to control the operation of the fan assembly based on the sixth speed parameter of the fan assembly.

[0142] In this embodiment, the rotation speed of at least one fan component and the power of at least one heating element of the heating device are determined by real-time collected indoor temperature parameters and air outlet height parameters. This achieves that the overall air outlet effect of the heating device meets the comfort requirements corresponding to the indoor temperature parameters, while also enabling independent control of the air outlet effect of air outlets with different height parameters, thus more flexibly meeting the user's heating needs.

[0143] It should be noted that the control device for the heating equipment provided in the above embodiments is only illustrated by the division of the above functional modules when executing the control method for the heating equipment. In practical applications, the above functions can be assigned to different functional modules as needed, that is, the internal structure of the equipment can be divided into different functional modules to complete all or part of the functions described above. In addition, the control device for the heating equipment provided in the above embodiments and the control method embodiments for the heating equipment belong to the same concept, and the implementation process is detailed in the method embodiments, which will not be repeated here.

[0144] The sequence numbers of the embodiments described above are for descriptive purposes only and do not represent the superiority or inferiority of the embodiments. In some cases, the actions or steps described in the claims can be performed in a different order than that shown in the embodiments and still achieve the desired result. Furthermore, the processes depicted in the drawings do not necessarily require a specific or sequential order to achieve the desired result. In some embodiments, multitasking and parallel processing are also possible or may be advantageous.

[0145] This application embodiment also provides a storage medium storing a computer program, which, when executed by a control component, implements the above-described functionality. Figures 3-10 The method of the illustrated embodiment, for detailed execution process, can be found in [reference needed]. Figures 3-10 The specific details of the illustrated embodiments will not be elaborated here.

[0146] Please see Figure 14 This is a schematic diagram of a heating device provided in an embodiment of this application. Figure 14 As shown, the heating device 500 includes a control component 501 and a memory 502. The control component 501 and the memory 502 are electrically connected.

[0147] The control component 501 is the control center of the heating device 500 and may include one or more processing cores. The control component 501 connects to various parts of the heating device 500 using various interfaces and lines. By running or calling computer programs stored in the memory 502, and by calling data stored in the memory 502, it executes various functions and processes data of the heating device 500, thereby providing overall control of the heating device 500. Optionally, the control component 501 may be implemented using at least one hardware form of Digital Signal Processing (DSP), Field Programmable Gate Array (FPGA), or Programmable Logic Array (PLA). The control component 501 may integrate one or more of the following: CPU, Graphics Processing Unit (GPU), and modem. The CPU primarily handles the operating system, user page, and applications; the GPU is responsible for rendering and drawing the displayed content; and the modem handles wireless communication. It is understood that the modem may also not be integrated into the control component 501 and may be implemented separately using a communication chip.

[0148] The memory 502 can be used to store software programs and modules. The control component 501 executes various functional applications and data processing by running the computer programs and modules stored in the memory 502. The memory 502 may mainly include a program storage area and a data storage area. The program storage area may store the operating system, computer programs required for at least one function, etc.; the data storage area may store data created based on the use of the heating device 500, etc.

[0149] Furthermore, memory 502 may include high-speed random access memory, and may also include non-volatile memory, such as at least one disk storage device, flash memory device, or other volatile solid-state storage device. Accordingly, memory 502 may also include a memory controller to provide control component 501 with access to memory 502.

[0150] In this embodiment, the control component 501 in the heating device 500 loads the instructions corresponding to the processes of one or more computer programs into the memory 502 according to the following steps, and the control component 501 runs the computer programs stored in the memory 502 to realize various functions, as follows:

[0151] Acquire indoor temperature parameters of the space where the heating device is located, collected by a temperature sensor;

[0152] The power parameters of the heating element and the rotational speed parameters of the fan assembly are determined based on the indoor temperature parameters and the height parameters of the air outlet.

[0153] Controlling the operation of the heating element based on its power parameters;

[0154] The operation of the fan components is controlled based on the rotational speed parameters of the fan components.

[0155] It should be understood that the device provided in this application embodiment is used to execute the control method of the heating device described above, and therefore can achieve the same effect as the above implementation method.

[0156] When using an integrated unit, the device may include a processing module and a storage module. Specifically, when the device is applied to a heating device, the processing module can be used to control and manage the operation of the heating device. The storage module can be used to support the execution of relevant program code by the heating device.

[0157] The processing module may be a control component or controller, which can implement or execute the various exemplary logic blocks, modules, and circuits described in conjunction with the disclosure of this application. The control component may also be a combination of computing functions, such as a combination of one or more microcontroller components, a combination of digital signal processing (DSP) and microcontroller components, etc., and the storage module may be a memory.

[0158] In addition, the device provided in this application embodiment may specifically be a chip, component or module. The chip may include a connected control component and a memory. The memory is used to store instructions. When the control component calls and executes the instructions, the chip can execute a control method for a heating device provided in the above embodiment.

[0159] This application also provides a computer-readable storage medium storing computer program code. When the computer program code is run on a computer, the computer executes the above-described related method steps to implement a control method for a heating device provided in the above embodiments.

[0160] This embodiment also provides a computer program product that, when run on a computer, causes the computer to perform the aforementioned related steps to implement a control method for a heating device provided in the above embodiment.

[0161] In this embodiment, the device, computer-readable storage medium, computer program product, or chip are all used to execute the corresponding methods provided above. Therefore, the beneficial effects they can achieve can be referred to the beneficial effects in the corresponding methods provided above, and will not be repeated here.

[0162] Through the above description of the embodiments, those skilled in the art will understand that, for the sake of convenience and brevity, only the division of the above functional modules is used as an example. In actual applications, the above functions can be assigned to different functional modules as needed, that is, the internal structure of the device can be divided into different functional modules to complete all or part of the functions described above.

[0163] In the embodiments provided in this application, it should be understood that the disclosed apparatus and methods can be implemented in other ways. For example, the apparatus embodiments described above are merely illustrative. For instance, the division of modules or units is only a logical functional division, and in actual implementation, there may be other division methods. For example, multiple units or components may be combined or integrated into another device, or some features may be ignored or not executed. Furthermore, the coupling or direct coupling or communication connection shown or discussed may be through some interfaces; the indirect coupling or communication connection between devices or units may be electrical, mechanical, or other forms.

[0164] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the scope of the technology disclosed in this application should be included within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of the claims.

Claims

1. A control method of a heating apparatus, characterized by, A control component for a heating device, the heating device including a temperature sensor, multiple air outlets, at least one heating element, and a fan assembly, wherein the air outlets of the heating device are arranged vertically, and the heating element and temperature sensor are respectively connected to the control component, the method comprising: The indoor temperature parameters of the space where the heating device is located are collected by the temperature sensor; The power parameters of the heating element and the rotational speed parameters of the fan assembly are determined based on the indoor temperature parameters and the height parameters of the air outlet. The operation of the heating element is controlled based on its power parameters. The operation of the fan assembly is controlled based on the rotational speed parameters of the fan assembly.

2. The method of claim 1, wherein, The fan assembly and the heating element are respectively associated with the air outlet.

3. The method of claim 2, wherein, The air outlet includes a first air outlet, each of the first air outlets corresponds to a first fan assembly, and multiple first air outlets correspond to a first heating element.

4. The method of claim 3, wherein, The process of determining the power parameters of the heating element and the rotational speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlet includes: The first rotational speed parameter of each of the first fan components is determined based on the indoor temperature parameter and the height parameter of the first air outlet. The first power parameter of the first heating element is determined based on the indoor temperature parameter.

5. The method of claim 3, wherein, The air outlet also includes a second air outlet, each of the second air outlets corresponding to a second fan assembly and each of the second air outlets corresponding to a second heating element.

6. The method of claim 5, wherein, The method of determining the power parameters of the heating element and the rotational speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlet further includes: The second rotation speed parameters of each second fan component are determined based on the indoor temperature parameters and the height parameters of the second air outlet. The second power parameters of each of the second heating elements are determined based on the indoor temperature parameters and the height parameters of the second air outlet.

7. The method of claim 2, wherein, The air outlet includes a third air outlet, and multiple third air outlets correspond to a third fan assembly, with each third air outlet corresponding to a third heating element.

8. The method of claim 7, wherein, The method of determining the power parameters of the heating element and the rotational speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlet further includes: The third rotational speed parameter of the third fan assembly is determined based on the indoor temperature parameter. The third power parameter of each of the third heating elements is determined based on the indoor temperature parameter and the height parameter of the third air outlet.

9. The method of claim 8, wherein, The air outlet includes a fourth air outlet, each of the fourth air outlets corresponds to a fourth fan assembly, and each of the fourth air outlets corresponds to a fourth heating element.

10. The method of claim 9, wherein, The method of determining the power parameters of the heating element and the rotational speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlet further includes: The fourth rotational speed parameters of each of the fourth fan components are determined based on the indoor temperature parameters and the height parameters of the fourth air outlet. The fourth power parameter of each of the fourth heating elements is determined based on the indoor temperature parameter and the height parameter of the fourth air outlet.

11. The method of claim 2, wherein, The air outlet includes a fifth air outlet, each of the fifth air outlets corresponds to a fifth fan assembly, and each of the fifth air outlets corresponds to a fifth heating element.

12. The method of claim 11, wherein, Determining the power parameters of the heating element and the rotational speed parameters of the fan assembly based on the indoor temperature parameters includes: The fifth rotational speed parameters of each of the fifth fan components are determined based on the indoor temperature parameters and the height parameters of the fifth air outlet. The fifth power parameter of each of the fifth heating elements is determined based on the indoor temperature parameter and the height parameter of the fifth air outlet.

13. The method of any one of claims 1-12, wherein, For any two adjacent air outlets, the heat flow of the air outlet at the first position is less than or equal to the heat flow of the air outlet at the second position, and the first position is higher than the second position.

14. The method of claim 1, wherein, The heating device further includes a partition, the partition corresponding to the air outlet, and the method further includes: The opening parameters of the baffle corresponding to each air outlet are determined based on the indoor temperature parameters. The partition is activated based on the opening parameters.

15. The method of claim 15, wherein, For any two adjacent partitions, the opening parameter of the partition at the first position is not greater than the opening parameter of the partition at the second position, and the first position is higher than the second position.

16. A control method of a heating apparatus, characterized by, A control component for a heating device, the heating device including a temperature sensor, multiple air outlets, a parameter selection interface, at least one heating element, and a fan assembly, wherein the air outlets of the heating device are arranged vertically, and the heating element, the temperature sensor, and the parameter selection interface are respectively connected to the control component, the method comprising: The sixth power parameter for the heating element and the sixth speed parameter for the fan assembly are obtained based on the parameter selection interface. The operation of the heating element is controlled based on the sixth power parameter of the heating element; The operation of the fan assembly is controlled based on the sixth speed parameter of the fan assembly.

17. A control device for a heating apparatus, characterized by comprising: An application is made in heating equipment, the heating equipment including a temperature sensor, multiple air outlets, at least one heating element, and a fan assembly. The air outlets of the heating equipment are arranged vertically. The heating element and the temperature sensor are respectively connected to the device. The device includes: The acquisition unit is used to acquire the indoor temperature parameters of the space where the heating device is located, collected by the temperature sensor. The determining unit is used to determine the power parameters of the heating element and the rotational speed parameters of the fan assembly based on the indoor temperature parameters and the height parameters of the air outlet; The first control unit is used to control the operation of the heating element based on the power parameters corresponding to the heating element; The second control unit is used to control the operation of the wind turbine assembly based on the rotational speed parameters corresponding to the wind turbine assembly.

18. A control device for a heating equipment, characterized in that, An application is made in heating equipment, the heating equipment including a temperature sensor, multiple air outlets, a parameter selection interface, at least one heating element, and a fan assembly. The air outlets of the heating equipment are arranged vertically. The heating element, the temperature sensor, and the parameter selection interface are respectively connected to the device. The device includes: The parameter acquisition unit is used to acquire the sixth power parameter for the heating element and the sixth speed parameter for the fan assembly based on the parameter selection interface. A heating control unit is used to control the operation of the heating element based on a sixth power parameter of the heating element. A speed control unit is used to control the operation of the fan assembly based on a sixth speed parameter of the fan assembly.

19. A heating device, characterized in that, The heating device includes: Memory, used to store executable program code; A control component for calling and running the executable program code from the memory, causing the heating device to perform the method as described in any one of claims 1 to 15.

20. A computer-readable storage medium, characterized in that, The computer-readable storage medium stores computer program code that, when executed, implements the method as described in any one of claims 1 to 16.