CN112068450B - Purifier and wall-mounted furnace linkage control method, system and device and purifier - Google Patents

Abstract

The application relates to a method, a system and a device for linkage control of a purifier and a wall-mounted furnace, the purifier and a storage medium. The method comprises the following steps: receiving a detection mode starting instruction, wherein the detection mode starting instruction is sent when the linked wall-mounted boiler detects and determines that the temperature of the heating water reaches a first temperature; determining a current heating area of the wall-mounted boiler according to the detection mode starting instruction; carrying out temperature detection on a current heating area of the wall-mounted boiler to obtain the detection temperature of the current heating area; and when the detected temperature is determined not to reach a second temperature corresponding to the first temperature, feeding back an increasing instruction to the wall-mounted furnace so that heating firepower of the wall-mounted furnace is increased. By adopting the method, the wall-mounted furnace and the purifier can be linked, and after the purifier detects that the indoor temperature does not reach the preset temperature, the purifier sends an instruction to the wall-mounted furnace to enable the wall-mounted furnace to adjust the firepower, so that manual adjustment is not needed, and the working efficiency is improved.

Description

Purifier and wall-mounted furnace linkage control method, system and device and purifier

Technical Field

The application relates to the technical field of computers, in particular to a method, a system, a device, a purifier and a storage medium for linkage control of the purifier and a wall-mounted furnace.

Background

A wall-hanging stove is a device for heating. The pipeline need be buried to below the floor when hanging stove heating, and when hanging stove normal during operation, the hot water of hanging stove flows through the pipeline for ground temperature rises, thereby reaches the heating effect. The comfort level of hanging stove compares the air conditioner and concentrates the heating equipment better, generally is applied to the independent heating of little house type under the dry environment in the north.

However, the conventional wall-mounted boiler is usually installed outdoors, so that the wall-mounted boiler cannot sense the heating effect in a heating room, the heating firepower of the wall-mounted boiler can be usually adjusted only by manual operation, and the working efficiency is reduced.

Disclosure of Invention

The invention provides a method, a system and a device for linkage control of a purifier and a wall-mounted boiler, and the purifier and the wall-mounted boiler and a storage medium, aiming at the problem that the wall-mounted boiler reduces the working efficiency through manual adjustment.

A method for linkage control of a purifier and a wall-hanging stove comprises the following steps:

receiving a detection mode starting instruction, wherein the detection mode starting instruction is sent when the linked wall-mounted furnace detects that the temperature of the heating water reaches a first temperature;

determining a current heating area of the wall-mounted boiler according to the detection mode starting instruction;

detecting the temperature of the current heating area of the wall-mounted boiler to obtain the detected temperature of the current heating area;

and when the detected temperature is determined not to reach the second temperature corresponding to the first temperature, feeding back an ascending instruction to the wall-hanging furnace, so that the wall-hanging furnace ascends the heating firepower.

In one embodiment, after determining the current heating area of the wall-hanging stove according to the detection mode start instruction, the method further includes:

performing air purification on a current heating area of the wall-mounted furnace, and detecting the air quality of the current heating area after air purification to obtain indoor air turbidity;

and when the indoor air pollution degree is larger than or equal to a preset first pollution threshold value, increasing air purification force and feeding back an ascending instruction to the wall-mounted furnace, so that heating firepower of the wall-mounted furnace is increased.

In one embodiment, the determining a current heating area of the wall-hanging stove according to the detection mode starting instruction includes:

acquiring heating area digital codes carried by the detection mode starting instruction, wherein each digital code in the heating area digital codes corresponds to each heating area covered by the wall-mounted boiler one by one;

and acquiring a digital code which is the same as a preset heating code from the digital codes of the heating areas, and determining the heating area corresponding to the digital code which is the same as the preset heating code as the current heating area.

In one embodiment, the detecting the temperature of the current heating area of the wall-hanging stove to obtain the detected temperature of the current heating area includes:

after the current heating area of the wall-mounted boiler is moved, temperature detection is carried out on the current heating area through an environment temperature sensing bulb;

and acquiring the detection temperature of the current heating area acquired by the temperature environment temperature sensing bulb.

In one embodiment, the method further comprises:

receiving outdoor air turbidity sent by the wall-mounted furnace; the outdoor air turbidity is obtained by detecting the outdoor ambient air quality by the wall-mounted furnace;

and displaying the outdoor air pollution turbidity, and increasing air purification strength to maintain indoor air quality when the outdoor air pollution turbidity is greater than or equal to a preset second pollution threshold value.

A linkage control system of a purifier and a wall-mounted furnace comprises the purifier and the wall-mounted furnace;

the wall-mounted boiler is used for generating a detection mode starting instruction and sending the detection mode starting instruction to the linked purifier when the temperature of the heating water is detected and determined to reach a first temperature;

the purifier is used for determining the current heating area of the wall-mounted boiler according to the received detection mode starting instruction; detecting the temperature of the current heating area of the wall-mounted boiler to obtain the detected temperature of the current heating area; when the detected temperature is determined not to reach a second temperature corresponding to the first temperature, generating an ascending instruction and feeding back the ascending instruction to the wall-mounted furnace;

the wall-mounted boiler is used for receiving the ascending instruction fed back by the purifier and ascending heating firepower according to the ascending instruction.

In one embodiment, the wall-mounted boiler is further used for acquiring a current heating area digital code when the temperature of the heating water is detected and determined to reach the first temperature;

and sending a detection mode starting instruction carrying the digital code of the heating area to the purifier.

In one of the embodiments, the first and second electrodes are,

the wall-mounted furnace is also used for detecting the air instruction quality of the outdoor environment to obtain the outdoor air pollution turbidity; when the outdoor air pollution degree is larger than or equal to a preset second pollution threshold value, sending the outdoor air pollution degree to the purifier;

the purifier is also used for displaying the outdoor air turbidity and increasing the air purification strength to maintain the indoor air quality.

A purifier and wall-hanging stove coordinated control apparatus, the apparatus comprising:

the system comprises a receiving module, a detecting module and a control module, wherein the receiving module is used for receiving a detecting mode starting instruction, and the detecting mode starting instruction is sent when a linked wall-mounted furnace detects that the temperature of heating water reaches a first temperature;

the determining module is used for determining the current heating area of the wall-mounted boiler according to the detection mode starting instruction;

the detection module is used for detecting the temperature of the current heating area of the wall-mounted boiler to obtain the detection temperature of the current heating area;

and the feedback module is used for feeding back an ascending instruction to the wall-hanging stove when the detected temperature is determined not to reach the second temperature corresponding to the first temperature, so that the heating firepower of the wall-hanging stove is increased.

A purifier comprises a memory and a processor, wherein the memory stores a computer program, and the processor realizes the steps of the linkage control method of the purifier and a wall-hanging stove when executing the computer program.

A computer-readable storage medium having stored thereon a computer program which, when executed by a processor, implements the steps of any of the above-described methods of linked control of a purifier and a wall-hanging stove.

According to the linkage control method, the system, the device, the purifier and the storage medium of the purifier and the wall-mounted furnace, when the wall-mounted furnace determines that the heating water reaches the first temperature, a detection mode opening instruction is sent to the purifier, the purifier determines the current heating area of the wall-mounted furnace according to the detection mode opening instruction, then temperature detection is carried out on the current heating area of the wall-mounted furnace, and when the detection temperature of the current heating area does not reach the second temperature corresponding to the first temperature, a rising instruction is fed back to the wall-mounted furnace, so that the heating power of the wall-mounted furnace rises. According to the method, through linkage of the wall-mounted furnace and the purifier, after the purifier detects that the indoor temperature does not reach the preset temperature, an instruction is sent to the wall-mounted furnace to enable the wall-mounted furnace to adjust the firepower, manual adjustment is not needed, and the working efficiency is improved.

Drawings

FIG. 1 is a diagram illustrating an exemplary embodiment of a method for controlling a purifier and a wall-hanging stove in a coordinated manner;

FIG. 2 is a schematic flow chart illustrating a method for controlling the operation of the boiler in conjunction with a purifier according to an embodiment;

FIG. 3 is a schematic flow chart illustrating a method for controlling the operation of the boiler in conjunction with a purifier;

FIG. 4 is a schematic diagram of a purifier sub-region spot detection function according to an embodiment;

FIG. 5 is a block diagram showing a configuration of a control unit for linking the purifier and the wall-hanging stove according to an embodiment;

FIG. 6 is a view showing an internal structure of the purifier in one embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The purifier and wall-hanging furnace linkage control method can be applied to the application environment shown in fig. 1. The purifier 102 is connected with the wall-hanging stove 104, and the connection includes a wired connection and a wireless connection. Including but not limited to WiFi, bluetooth, etc. Referring to fig. 1, the purifier 102 communicates with the wall-mounted stove 104 via a WiFi router 106 connection.

Specifically, after the wall-mounted boiler 104 is started to operate, the temperature of the heating water is detected; when the wall-mounted boiler 104 determines that the temperature of the heating water reaches the first temperature, a detection mode start instruction is generated and sent to the purifier 102. The purifier 102 receives a detection mode starting instruction; the purifier 102 determines the current heating area of the wall-mounted boiler 104 according to the detection mode starting instruction; the purifier 102 detects the temperature of the current heating area of the wall-mounted boiler 104 to obtain the detected temperature of the current heating area; when the purifier 102 determines that the detected temperature does not reach a second temperature corresponding to the first temperature, an increase instruction is fed back to the wall-mounted furnace 104, so that the wall-mounted furnace 104 increases heating power.

In one embodiment, as shown in fig. 2, a method for controlling a purifier and a wall-hanging stove in a linkage manner is provided, which is described by taking the purifier in fig. 1 as an example, and comprises the following steps:

step S202, receiving a detection mode starting instruction, wherein the detection mode starting instruction is sent when the linked wall-mounted boiler detects that the temperature of the heating water reaches a first temperature.

The detection mode starting instruction is sent by the wall-mounted furnace linked with the purifier and used for indicating the purification to carry out detection work. The wall-mounted boiler is a gas wall-mounted boiler, which is called as a gas wall-mounted heating boiler. The water heater is a water heater using natural gas as energy. The heating water is water resource used when the wall-mounted furnace is used for increasing indoor temperature, namely water used in the heating process. The first temperature is a temperature of heating water, and may be any temperature set in advance, or may be a temperature of heating water corresponding to a temperature required for indoor heating. For example, if heating needs to maintain the indoor temperature at 25 degrees celsius, and heating can reach the indoor temperature of 25 degrees celsius can be achieved only by heating the heating water to 35 degrees celsius, 35 degrees celsius is the first temperature. Linkage is understood to mean that the purifier and the wall-hanging stove are connected and in communication with each other. It should be understood that, if the purifier or the wall-hanging stove is connected to a plurality of devices at the same time, when it is necessary to operate in conjunction with one of the connected devices, both devices should be operated in the conjunction mode. That is, the purifier and the wall-hanging stove are not only in a connected state, but also in a state in which both are in an open linkage mode. By switching on the linkage mode, the linked device can be accurately determined in the case where a plurality of connected devices exist.

Specifically, when the wall-hanging stove is turned on to operate, the wall-hanging stove starts to heat the heating water. In the process of heating the heating water, the wall-mounted boiler detects the temperature in real time or at certain time intervals during heating to obtain the temperature of the heating water. And when the temperature of the heating water is detected once, the wall-mounted furnace compares the temperature of the heating water with the first temperature. If the wall-mounted furnace determines that the temperature of the heating water does not reach (is lower than) the first temperature, the wall-mounted furnace can determine that the heating water does not reach the required temperature at the moment. Therefore, the wall-hanging stove continues to heat and detect the temperature of the heating water. And if the wall-mounted boiler detects that the temperature of the heating water reaches (is greater than or equal to) the first temperature, the wall-mounted boiler can determine that the heating of the heating water reaches the temperature required for heating at the moment, and correspondingly, the indoor temperature in the heating area also reaches the indoor temperature required for heating at the moment. Therefore, in order to confirm whether the temperature of the heating area reaches the indoor temperature required for heating, the wall-hanging stove generates a detection mode opening command and sends the detection mode opening command to the purifier which is located indoors and is linked with the wall-hanging stove. Therefore, the purifier starts to enter the detection work after receiving a detection mode starting instruction sent by the linked wall-mounted furnace.

And step S204, determining the current heating area of the wall-mounted boiler according to the detection mode starting instruction.

The current heating area refers to an area where a heating function is currently turned on, for example, a room where heating is currently turned on. Because the energy use is saved according to user's demand, the heating of current hanging stove can have independent room or some room and open the heating function. So in order to be able to accurately determine the area that needs to be detected before the detection of the purifier, the purifier should first determine the current heating area of the wall-hanging stove.

Specifically, after the purifier receives a detection mode starting instruction sent by the linked wall-mounted boiler, the current heating area of the wall-mounted boiler is determined according to identification information carried in the detection mode starting instruction. That is, when the hanging stove sends the detection mode and opens the instruction to the clarifier, can carry the identification information that the clarifier distinguished current heating region of being convenient for in the detection mode opening instruction. For example, the identification information may be a unique number, name, or the like corresponding to the heating area. Furthermore, when the purifier responds to the detection mode starting instruction to prepare for starting detection work, firstly, the carried identification information is obtained from the detection mode starting instruction to determine the area where heating is currently started, and the current heating area is obtained. For example, assuming that the number a corresponds to the room a, when the detection mode start instruction carries the number a, the purifier may determine that the room a corresponding to the number a is the current heating area.

And S206, detecting the temperature of the current heating area of the wall-mounted furnace to obtain the detected temperature of the current heating area.

Specifically, after the purifier determines the current heating area of the wall-mounted boiler, the purifier detects the temperature of the current heating area through the environmental temperature sensing bulb, so as to obtain the detected temperature of the current heating area.

And S208, when the detected temperature is determined not to reach the second temperature corresponding to the first temperature, feeding back an increasing instruction to the wall-mounted furnace so that the wall-mounted furnace increases heating power.

Here, the second temperature is a temperature corresponding to the first temperature, and since the first temperature is a temperature of the heating water, the second temperature may be understood as an indoor temperature corresponding to the temperature of the heating water. For example, if the indoor temperature corresponding to the temperature of the heating water at 35 degrees celsius is 25 degrees celsius, 35 degrees celsius is a first temperature, and 25 degrees celsius is a second temperature corresponding to the first temperature. The ascending instruction is an instruction which is generated by the purifier and sent to the linked wall-mounted boiler and used for instructing the wall-mounted boiler to increase heating power.

Specifically, after the purifier detects the detected temperature of the current heating area, the detected temperature is compared with a second temperature corresponding to the first temperature. If the purifier determines that the detected temperature does not reach (is less than) the second temperature, it may be determined that the temperature in the current heating area does not reach the indoor temperature corresponding to the current heating water temperature. The purifier generates a rising instruction and feeds the rising instruction back to the wall-hanging stove. After the wall-mounted boiler receives the ascending instruction, heating firepower is increased to increase the temperature of the heating water, and then the indoor temperature of the current heating area reaches a second temperature corresponding to the first temperature.

According to the linkage control method of the purifier and the wall-mounted furnace, when the wall-mounted furnace determines that the heating water reaches the first temperature, a detection mode opening instruction is sent to the purifier, the purifier determines the current heating area of the wall-mounted furnace according to the detection mode opening instruction, then temperature detection is carried out on the current heating area of the wall-mounted furnace, and when the detection temperature of the current heating area does not reach the second temperature corresponding to the first temperature, a rising instruction is fed back to the wall-mounted furnace, so that heating firepower of the wall-mounted furnace rises. According to the method, through linkage of the wall-mounted furnace and the purifier, after the purifier detects that the indoor temperature does not reach the preset temperature, an instruction is sent to the wall-mounted furnace to enable the wall-mounted furnace to adjust the firepower, manual adjustment is not needed, and the working efficiency is improved

In one embodiment, as shown in fig. 3, after step S204, the method further includes:

and step S210, performing air purification on the current heating area of the wall-mounted furnace, and detecting the air quality of the current heating area after air purification to obtain indoor air pollution turbidity.

And step S212, when the indoor air pollution degree is greater than or equal to a preset first pollution threshold value, increasing air purification strength and feeding back an ascending instruction to the wall-mounted furnace so that heating fire power of the wall-mounted furnace is increased.

The air pollution level is a value obtained by detecting the air quality by the purifier, and is used for representing the air pollution level, including but not limited to dust concentration, bacteria concentration, and the like. The first dirty threshold is a preset critical value for measuring the air quality of a heating area. Greater than or equal to the first dirty threshold indicates that the current air quality is poor, and less than the first dirty threshold indicates that the current air quality is good. That is, the larger the air quality is, the worse the air quality is, as compared to the first threshold value for turbidity, whereas the smaller the air quality is, the better the air quality is.

Specifically, after the air purifier determines the current heating area of the wall-hanging stove, the air purifier moves to the current heating area. And then, detecting the air quality of the current heating area in real time to obtain the indoor air pollution turbidity. And when the indoor air quality is determined to be poor according to the comparison between the indoor air pollution degree and the first pollution degree threshold value, the purifier is started to carry out air purification on the current heating area. After the purification is completed, the purifier can detect the air quality of the current heating area again to obtain the indoor air turbidity again. And if the purified air quality is determined to be in a poor state by comparing with the first dirty threshold value, the purifier generates an ascending instruction and sends the ascending instruction to the wall-mounted furnace. After the wall-mounted boiler receives the ascending instruction, heating firepower is increased to increase the temperature of the heating water. Because the heating of utilizing hanging stove leads to the environment damp and hot different from the air conditioner heating, the heating of hanging stove makes the heating region belong to the dry and hot state to the heating water pipeline sets up inside ground again usually. Therefore, once the temperature of a room heated by the wall-hanging stove is increased, dust and bacteria in the room, particularly on the ground, are lifted. Meanwhile, the purifier increases the dust absorption and the sterilization power so as to increase the air purification strength, so that raised dust and bacteria are purified, and the purification efficiency can be improved. When the air quality is detected and determined to be good, the purifier can send the instruction to the wall-hanging stove again, so that the wall-hanging stove reduces firepower to reduce the heating temperature to a comfortable temperature range. The comfortable temperature range can be set according to different temperature sensing of the users in actual use.

In this embodiment, through the characteristic of hanging stove heating, raise the dust with the temperature rise in the room and be convenient for the clarifier to purify to improve the efficiency of purification.

In one embodiment, as shown in fig. 4, a schematic diagram of a function of detecting the purifier at different regions at fixed points is provided, and a method for controlling the purifier and the wall-hanging furnace in a linkage manner is described with reference to fig. 4.

Specifically, referring to fig. 4, the heating area includes four heating areas of room 1, room 2, room 3, and room 4 in total. When the purifier determines that the room 1 is the current heating area, the purifier moves into the room 1. Then, the temperature in the room 1 is detected by the environmental bulb. And detecting the air quality of the room 1 after purifying the air in the room 1 to obtain the indoor air pollution degree of the room 1. And when the detected temperature is lower than the second temperature, the purifier generates a rising instruction and sends the rising instruction to the wall-mounted furnace installed outdoors to increase the firepower and raise the temperature to the second temperature. Or, when the indoor air turbidity is greater than or equal to the first turbidity threshold value, the purifier generates a rising instruction and sends the rising instruction to the wall-hanging stove, so that the wall-hanging stove increases the firepower, raises the temperature, raises the dust and bacteria, and facilitates the purifier which increases the purification strength to purify air. In this embodiment, the clarifier through autonomic removal removes and carries out temperature detection and air purification, can more accurate more extensive temperature and the air-purifying of each indoor region of detection.

In one embodiment, step S204 includes: acquiring heating area digital codes carried by a detection mode starting instruction, wherein each digital code in the heating area digital codes corresponds to each heating area covered by the wall-mounted boiler one by one; and acquiring a digital code which is the same as the preset heating code from the digital code of the heating area, and determining the heating area corresponding to the digital code which is the same as the preset heating code as the current heating area.

Wherein, because hanging stove distinguishes regional heating in preparation, can the function of the regional quantity of real time control heating. Therefore, the heating area digital code is a code for identifying the heating state of each heating area covered by the wall-hanging stove. The preset heating code is a digital code preset to indicate that heating is turned on in a heating area.

The digital code of this embodiment is preferably binary 1, 0 in combination with the characteristics of the control program. When the heating area is started for heating by 1, the heating area is not started for heating by 0. On the contrary, when the heating area is started by 0, the heating area is not started by 1. Taking 1 for heating and 0 for not heating as an example, if the heating area covered by the wall-hanging stove includes three bedrooms B1, B2 and B3 and two living rooms T1 and T2. When the two rooms are both opened for heating, the digital code of the heating area is 11111. Assuming that the sequence of the heating area digital codes is T1, T2, B1, B2 and B3, when only the heating of the B3 bedroom is turned on, the current heating area digital code is 00001.

Specifically, when the hanging stove sends the detection mode to the clarifier and opens the instruction, in order to facilitate the clarifier to know the current heating region of opening the heating at present. The wall-mounted boiler carries the digital code of the heating area in the detection mode starting instruction and sends the digital code to the purifier. And when the purifier determines the current heating area, acquiring the carried heating area digital code from the detection mode starting command. Then, the purifier compares each digital code in the heating area digital codes with a preset heating code. And determining the same number code as the preset heating code, wherein the same number code as the preset heating code indicates that the heating area corresponding to the number code is started, namely the current heating area is determined.

In addition, when the air purifier determines that the current heating areas of the wall-mounted boiler include two or more, the air purifier can sequentially move to each current heating area to perform temperature detection and air quality detection according to a preset area priority or the sequence of the digital codes of the heating areas, so that accurate detection of each area is ensured.

In this embodiment, the current heating area of hanging stove is confirmed through the regional digital code of heating that each heating area one-to-one sent with hanging stove to the clarifier, has improved the regional accuracy of confirming of heating.

In one embodiment, step S206 includes: after the mobile wall-mounted boiler moves to a current heating area of the wall-mounted boiler, temperature detection is carried out on the current heating area through an environment temperature sensing bag; and acquiring the detection temperature of the current heating area acquired by the temperature-environment bulb.

Specifically, the purifier in this embodiment is a purifier that can move autonomously for detection, and the position of the purifier is not fixed in a certain position. Therefore, after the purifier determines the current heating area of the wall-hanging stove, the purifier needs to move to the current heating area in order to be able to detect the temperature of the area. And then, after the purifier moves to the current heating area, detecting the ambient temperature of the purifier by opening the ambient temperature sensing bulb to obtain the detection temperature of the current heating area. The environment thermal bulb is a temperature sensor for detecting the environment temperature. In this embodiment, the purifier that moves by oneself moves and carries out temperature detection, can be more accurate more extensive each regional temperature in detection room.

In one embodiment, the method for controlling the purifier and the wall-hanging stove in a linkage manner further comprises the following steps: receiving outdoor air pollution turbidity sent by the wall-mounted furnace; the outdoor air turbidity is obtained by detecting the outdoor ambient air quality by the wall-mounted furnace; and displaying the outdoor air pollution degree, and increasing the air purification strength to maintain the indoor air quality when the outdoor air pollution degree is greater than or equal to a preset second pollution threshold value.

The second dirty threshold value is a preset critical value for measuring the quality of outdoor air where the wall-mounted boiler is located. A second dirty threshold greater than or equal to indicates poor current outdoor air quality, and a second dirty threshold less than indicates good current outdoor air quality. That is, the larger the second threshold value of fouling, the worse the outdoor air quality, whereas the smaller the outdoor air quality, the better. The second contamination threshold may or may not be equal to the first contamination threshold. The setting can be based on different requirements of indoor and outdoor air quality, and is not limited herein.

Specifically, the wall-mounted boiler is generally installed in an outdoor environment such as a balcony, and therefore the wall-mounted boiler can detect the air quality of the outdoor environment by its own air quality detection device, thereby obtaining the outdoor air turbidity and sending it to the coupled purifier. When the clarifier received outdoor air dirty turbidity, the dirty degree of outdoor air was shown on the display screen of clarifier, and the user of being convenient for knows outdoor air quality. Simultaneously, the purifier acquires a preset second dirty threshold. Then, the purifier compares the outdoor air pollution degree with a preset second pollution degree threshold value. If the outdoor air quality is determined to be poor, the air purification is increased by increasing the dust absorption and sterilization power, so that the better indoor air quality can be maintained when the outdoor air quality is poor.

In this embodiment, through the linkage of indoor purification ware and outdoor hanging stove, the clarifier of being convenient for acquires outdoor air quality and adjusts the purification dynamics according to outdoor air quality condition to improve the efficiency of purification.

In one embodiment, another method for controlling a purifier and a wall-hanging stove in a linkage manner is provided, which is exemplified by applying the method to the wall-hanging stove in fig. 1, and comprises the following steps:

step 1, detecting the temperature of heating water after the wall-mounted boiler is started to operate. Specifically, the wall-mounted boiler detects the water temperature through a temperature sensing bulb (NTC resistor) to obtain the temperature of the heating water.

And 2, generating a detection mode starting instruction and acquiring a current heating area digital code when the temperature of the heating water reaches the first temperature. Specifically, the wall-mounted boiler compares the temperature of the heating water with a first temperature, and generates a detection mode starting instruction and acquires a current heating area digital code when the temperature of the heating water is determined to be greater than or equal to the first temperature.

And 3, transmitting the digital codes of the heating areas to a linked purifier in a detection mode starting instruction. After the purifier receives the detection mode starting instruction, the current heating area of the wall-mounted furnace is determined according to the carried heating area digital code. Then, the cleaner moves to the current heating area to check the temperature and air quality of the area. And when the purifier determines that the detected temperature is lower than a second temperature corresponding to the first temperature, the purifier generates an ascending instruction and feeds the ascending instruction back to the wall-mounted furnace. Or when the purifier determines that the air pollution degree detected by the air quality is greater than or equal to the first pollution threshold value, the purifier increases the purification strength and simultaneously generates an ascending instruction to feed back to the wall-mounted furnace. After the wall-mounted boiler receives the ascending instruction, the firepower is increased to increase the heating temperature, so that the heating area reaches a second temperature. And, raise dust and bacterium through the high temperature of dry heat and be convenient for the clarifier to carry out air purification.

And 4, detecting the air quality of the outdoor environment by the wall-mounted furnace through the air quality detection device of the wall-mounted furnace to obtain the outdoor air pollution turbidity. When the wall-mounted furnace detects that the outdoor air pollution turbidity is obtained, the outdoor air pollution turbidity is compared with a preset second pollution threshold value. And if the wall-mounted furnace determines that the outdoor air quality is poor, sending the air turbidity corresponding to the poor quality to the purifier. After the purifier receives the outdoor air turbidity, the outdoor air turbidity is displayed on a display screen of the purifier, so that a user can know the outdoor air quality conveniently. Meanwhile, the air purifier increases air purification by increasing dust absorption and sterilization power, and is used for maintaining good indoor air quality as much as possible when the outdoor air quality is poor.

In one embodiment, when the wall-mounted boiler is started to operate, the wall-mounted boiler can also directly send a detection mode starting instruction to the linked purifier at any time point. And, the specified temperature is carried in the transmission detection mode start instruction. After the purifier receives the detection mode starting instruction, the current heating area is determined based on identification information carried by the detection mode starting instruction, such as a serial number or a heating area digital code, and then the current heating area is moved to carry out temperature detection. The sensed temperature is then compared to a specified temperature and, upon determining that the sensed temperature is greater than or equal to the sensed temperature, indicates that the current heating has reached the desired temperature for heating. At this time, the scrubber may send a maintenance instruction to the wall-hanging stove. When the wall-mounted boiler receives the maintaining instruction, the heating temperature of the heating at the moment can be determined to reach the temperature required by the heating, and the heating temperature is maintained for heating. In this embodiment, the clarifier through directly giving the linkage sends the instruction that carries the assigned temperature and realizes the control of hanging stove, need not artifical the regulation, has improved work efficiency.

It should be understood that although the various steps in the flow charts of fig. 2-3 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least some of the steps in fig. 2-3 may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, which are not necessarily performed in sequence, but may be performed in turn or alternately with other steps or at least some of the other steps.

In one embodiment, a purifier and wall-hanging stove coordinated control system is provided and includes a purifier 102 and a wall-hanging stove 104. The method for controlling the purifier and the wall-hanging stove in a linkage manner is explained in detail through a linkage control system of the purifier and the wall-hanging stove.

Specifically, after the wall-hanging stove 104 is started to operate, the temperature of the heating water is detected. And when the temperature of the heating water reaches a first temperature, generating a detection mode starting instruction and acquiring a current heating area digital code. Then, the wall-mounted boiler 104 sends a heating area digital code to the scrubber 102 with a detection mode on command.

The purifier 102 receives the detection mode starting instruction, and determines the current heating area of the wall-mounted furnace 104 according to the heating area digital code carried by the detection mode starting instruction. Then, the scrubber 102 moves to the current heating area, and temperature detection and air quality detection are performed on the area. If the detected temperature of the current heating area does not reach the second temperature corresponding to the first temperature, the purifier 102 generates an increasing instruction and feeds the increasing instruction back to the wall-hanging stove 104 to increase the firepower so as to increase the temperature of the current heating area to the second temperature. Or, when the purifier 102 detects that the air quality of the current heating area is always in a poor state, an ascending instruction can be generated and fed back to the wall-hanging stove 104 to increase the fire power to raise the dust and bacteria in the current heating area, and at the moment, the purifier 102 increases the purification strength synchronously to purify the raised dust and bacteria, so that the purification efficiency is improved.

The wall-mounted boiler 104 is also used for detecting the air quality of the outdoor environment through an air quality detection device of the wall-mounted boiler, so as to obtain the outdoor air pollution turbidity. When it is determined that the outdoor air turbidity is greater than or equal to the preset second turbidity threshold value, the wall-hanging stove 104 feeds back the outdoor air turbidity to the purifier 102.

The purifier 102 is further configured to display the outdoor air pollution degree on a display screen of the purifier 102 after receiving the outdoor air pollution degree, so that a user can know the outdoor air quality conveniently. Meanwhile, the cleaner 102 increases air cleaning by increasing dust-suction and sterilization power for maintaining good indoor air quality as much as possible when outdoor air quality is poor.

In one embodiment, as shown in fig. 5, there is provided a purifier and wall-hanging stove linkage control device, comprising: a receiving module 502, a determining module 504, a detecting module 506, and a feedback module 508, wherein:

the receiving module 502 is configured to receive a detection mode starting instruction, and the detection mode starting instruction is sent when the linked wall-mounted boiler detects that the temperature of the heating water reaches a first temperature.

The determining module 504 is configured to determine a current heating area of the wall-hanging stove according to the detection mode starting instruction.

The detection module 506 is configured to perform temperature detection on the current heating area of the wall-mounted furnace to obtain a detected temperature of the current heating area.

The feedback module 508 is configured to feed back an increase instruction to the wall-mounted boiler when it is determined that the detected temperature does not reach the second temperature corresponding to the first temperature, so that heating power of the wall-mounted boiler is increased.

In one embodiment, the detection module 506 is further configured to perform air purification on the current heating area of the wall-hanging stove, and detect the air quality of the current heating area after the air purification to obtain indoor air turbidity; the feedback module 508 is further configured to feed back an increasing instruction to the wall-mounted boiler when the indoor air turbidity is greater than or equal to a preset first turbidity threshold value, so that the wall-mounted boiler increases heating power; the linkage control device of the purifier and the wall-mounted furnace further comprises an adjusting module, and the adjusting module is used for increasing air purification strength when the indoor air turbidity is larger than or equal to a preset first turbidity threshold value.

In one embodiment, the determining module 504 is further configured to obtain a heating area digital code carried by the detection mode starting instruction, where each digital code in the heating area digital code corresponds to each heating area covered by the wall-mounted boiler one by one; and acquiring a digital code which is the same as the preset heating code from the digital code of the heating area, and determining the heating area corresponding to the digital code which is the same as the preset heating code as the current heating area.

In one embodiment, the detection module 506 is further configured to detect the temperature of the current heating area through the environmental temperature sensing bulb after moving to the current heating area of the wall-hanging stove; and acquiring the detection temperature of the current heating area acquired by the temperature-environment bulb.

In one embodiment, the receiving module 502 is further configured to receive outdoor air turbidity sent by the wall-hanging stove; the outdoor air turbidity is obtained by detecting the outdoor ambient air quality by the wall-mounted furnace; the linkage control device of the purifier and the wall-mounted furnace also comprises a display module for displaying outdoor air turbidity; the adjusting module is also used for increasing air purification strength to maintain indoor air quality when the outdoor air turbidity is greater than or equal to a preset second turbidity threshold value.

For specific limitations of the purifier and wall-hanging stove linkage control device, reference may be made to the above limitations of the purifier and wall-hanging stove linkage control method, and details thereof are not repeated here. All or part of the modules in the linkage control device of the purifier and the wall-hanging furnace can be realized by software, hardware and the combination thereof. The modules can be embedded in a hardware form or independent from a processor in the purifier, and can also be stored in a memory in the purifier in a software form, so that the processor can call and execute the corresponding operations of the modules.

In one embodiment, a purifier is provided, the internal structure of which can be as shown in fig. 6. The purifier comprises a processor, a memory, a communication interface, a display screen and an input device which are connected through a system bus. Wherein the processor of the purifier is configured to provide computational and control capabilities. The memory of the purifier comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The communication interface of the purifier is used for carrying out wired or wireless communication with an external terminal, and the wireless communication can be realized through WIFI, an operator network, NFC (near field communication) or other technologies. The computer program is executed by a processor to realize a linkage control method of the purifier and the wall-hanging stove. The display screen of the purifier can be a liquid crystal display screen or an electronic ink display screen, and the input device of the purifier can be a touch layer covered on the display screen, a key, a track ball or a touch pad arranged on the shell of the purifier, an external keyboard, a touch pad or a mouse and the like.

It will be understood by those skilled in the art that the configuration shown in figure 6 is a block diagram of only a portion of the configuration associated with the present application and does not constitute a limitation on the purifier to which the present application is applied, and that a particular purifier may include more or fewer components than shown, or some components may be combined, or have a different arrangement of components.

In one embodiment, there is provided a purifier comprising a memory and a processor, the memory having stored therein a computer program that when executed by the processor performs the steps of:

receiving a detection mode starting instruction, wherein the detection mode starting instruction is sent when the linked wall-mounted boiler detects and determines that the temperature of the heating water reaches a first temperature;

determining a current heating area of the wall-mounted boiler according to the detection mode starting instruction;

carrying out temperature detection on a current heating area of the wall-mounted boiler to obtain the detection temperature of the current heating area;

and when the detected temperature is determined not to reach a second temperature corresponding to the first temperature, feeding back an increasing instruction to the wall-mounted furnace so that heating firepower of the wall-mounted furnace is increased.

In one embodiment, the processor, when executing the computer program, further performs the steps of: carry out air purification to the current heating region of hanging stove, detect the regional air quality of current heating after the air purification, obtain the dirty turbidity of indoor air when indoor air dirty degree is greater than or equal to the first dirty threshold value of presetting, increase the air purification dynamics and feed back the instruction that rises and give the hanging stove for the hanging stove rises the heating firepower.

In one embodiment, the processor, when executing the computer program, further performs the steps of: acquiring heating area digital codes carried by a detection mode starting instruction, wherein each digital code in the heating area digital codes corresponds to each heating area covered by the wall-mounted boiler one by one; and acquiring a digital code which is the same as the preset heating code from the digital code of the heating area, and determining the heating area corresponding to the digital code which is the same as the preset heating code as the current heating area.

In one embodiment, the processor, when executing the computer program, further performs the steps of: after the mobile wall-mounted boiler moves to a current heating area of the wall-mounted boiler, temperature detection is carried out on the current heating area through an environment temperature sensing bag; and acquiring the detection temperature of the current heating area acquired by the temperature-environment bulb.

In one embodiment, the processor, when executing the computer program, further performs the steps of: receiving outdoor air pollution turbidity sent by the wall-mounted furnace; the outdoor air turbidity is obtained by detecting the outdoor ambient air quality by the wall-mounted furnace; and displaying the outdoor air pollution degree, and increasing the air purification strength to maintain the indoor air quality when the outdoor air pollution degree is greater than or equal to a preset second pollution threshold value.

In one embodiment, a computer-readable storage medium is provided, having a computer program stored thereon, which when executed by a processor, performs the steps of:

receiving a detection mode starting instruction, wherein the detection mode starting instruction is sent when the linked wall-mounted boiler detects and determines that the temperature of the heating water reaches a first temperature;

determining a current heating area of the wall-mounted boiler according to the detection mode starting instruction;

carrying out temperature detection on a current heating area of the wall-mounted boiler to obtain the detection temperature of the current heating area;

and when the detected temperature is determined not to reach a second temperature corresponding to the first temperature, feeding back an increasing instruction to the wall-mounted furnace so that heating firepower of the wall-mounted furnace is increased.

In one embodiment, the computer program when executed by the processor further performs the steps of: carry out air purification to the current heating region of hanging stove, detect the regional air quality of current heating after the air purification, obtain the dirty turbidity of indoor air when indoor air dirty degree is greater than or equal to the first dirty threshold value of presetting, increase the air purification dynamics and feed back the instruction that rises and give the hanging stove for the hanging stove rises the heating firepower.

In one embodiment, the computer program when executed by the processor further performs the steps of: acquiring heating area digital codes carried by a detection mode starting instruction, wherein each digital code in the heating area digital codes corresponds to each heating area covered by the wall-mounted boiler one by one; and acquiring a digital code which is the same as the preset heating code from the digital code of the heating area, and determining the heating area corresponding to the digital code which is the same as the preset heating code as the current heating area.

In one embodiment, the computer program when executed by the processor further performs the steps of: after the mobile wall-mounted boiler moves to a current heating area of the wall-mounted boiler, temperature detection is carried out on the current heating area through an environment temperature sensing bag; and acquiring the detection temperature of the current heating area acquired by the temperature-environment bulb.

In one embodiment, the computer program when executed by the processor further performs the steps of: receiving outdoor air pollution turbidity sent by the wall-mounted furnace; the outdoor air turbidity is obtained by detecting the outdoor ambient air quality by the wall-mounted furnace; and displaying the outdoor air pollution degree, and increasing the air purification strength to maintain the indoor air quality when the outdoor air pollution degree is greater than or equal to a preset second pollution threshold value.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical storage, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A linkage control method of a purifier and a wall-mounted furnace is characterized by being applied to the purifier, and the method comprises the following steps:

receiving a detection mode starting instruction, wherein the detection mode starting instruction is sent when the linked wall-mounted furnace detects that the temperature of the heating water reaches a first temperature;

determining a current heating area of the wall-mounted boiler according to the detection mode starting instruction;

detecting the temperature of the current heating area of the wall-mounted boiler to obtain the detected temperature of the current heating area;

when the detected temperature is determined not to reach a second temperature corresponding to the first temperature, feeding back an increasing instruction to the wall-mounted furnace to enable the wall-mounted furnace to increase heating power;

performing air purification on a current heating area of the wall-mounted furnace, and detecting the air quality of the current heating area after air purification to obtain indoor air turbidity;

and when the indoor air pollution degree is larger than or equal to a preset first pollution threshold value, increasing air purification force and feeding back an ascending instruction to the wall-mounted furnace, so that heating firepower of the wall-mounted furnace is increased.

2. The method according to claim 1, wherein the determining a current heating area of the wall-hanging stove according to the detection mode turn-on command comprises:

acquiring heating area digital codes carried by the detection mode starting instruction, wherein each digital code in the heating area digital codes corresponds to each heating area covered by the wall-mounted boiler one by one;

and acquiring a digital code which is the same as a preset heating code from the digital codes of the heating areas, and determining the heating area corresponding to the digital code which is the same as the preset heating code as the current heating area.

3. The method according to claim 1, wherein the detecting the temperature of the current heating area of the wall-hanging stove to obtain the detected temperature of the current heating area comprises:

after the current heating area of the wall-mounted boiler is moved, temperature detection is carried out on the current heating area through an environment temperature sensing bulb;

and acquiring the detection temperature of the current heating area acquired by the temperature environment temperature sensing bulb.

4. The method of claim 1, further comprising:

receiving outdoor air turbidity sent by the wall-mounted furnace; the outdoor air turbidity is obtained by detecting the outdoor ambient air quality by the wall-mounted furnace;

and displaying the outdoor air pollution turbidity, and increasing air purification strength to maintain indoor air quality when the outdoor air pollution turbidity is greater than or equal to a preset second pollution threshold value.

5. A linkage control system of a purifier and a wall-mounted furnace is characterized by comprising the purifier and the wall-mounted furnace;

the wall-mounted boiler is used for generating a detection mode starting instruction and sending the detection mode starting instruction to the linked purifier when the temperature of the heating water is detected and determined to reach a first temperature;

the purifier is used for determining the current heating area of the wall-mounted boiler according to the received detection mode starting instruction; detecting the temperature of the current heating area of the wall-mounted boiler to obtain the detected temperature of the current heating area; when the detected temperature is determined not to reach a second temperature corresponding to the first temperature, generating an ascending instruction and feeding back the ascending instruction to the wall-mounted furnace; performing air purification on a current heating area of the wall-mounted furnace, and detecting the air quality of the current heating area after air purification to obtain indoor air turbidity; when the indoor air pollution degree is larger than or equal to a preset first pollution threshold value, increasing air purification force and feeding back an ascending instruction to the wall-mounted furnace to enable the wall-mounted furnace to ascend heating power;

the wall-mounted boiler is used for receiving the ascending instruction fed back by the purifier and ascending heating firepower according to the ascending instruction.

6. The system of claim 5, wherein the wall hanging stove is further configured to,

when the temperature of the heating water is detected and determined to reach a first temperature, acquiring a current heating area digital code;

and sending a detection mode starting instruction carrying the digital code of the heating area to the purifier.

7. The system of claim 5,

the wall-mounted furnace is also used for detecting the air instruction quality of the outdoor environment to obtain the outdoor air pollution turbidity; when the outdoor air pollution degree is larger than or equal to a preset second pollution threshold value, sending the outdoor air pollution degree to the purifier;

the purifier is also used for displaying the outdoor air turbidity and increasing the air purification strength to maintain the indoor air quality.

8. A gang control of a purifier and a wall-hanging stove, the gang control comprising:

the system comprises a receiving module, a detecting module and a control module, wherein the receiving module is used for receiving a detecting mode starting instruction, and the detecting mode starting instruction is sent when a linked wall-mounted furnace detects that the temperature of heating water reaches a first temperature;

the determining module is used for determining the current heating area of the wall-mounted boiler according to the detection mode starting instruction;

the detection module is used for detecting the temperature of the current heating area of the wall-mounted boiler to obtain the detection temperature of the current heating area;

the feedback module is used for feeding back an increasing instruction to the wall-mounted furnace when the detected temperature is determined not to reach a second temperature corresponding to the first temperature, so that heating power of the wall-mounted furnace is increased;

the detection module is also used for carrying out air purification on the current heating area of the wall-mounted furnace, and detecting the air quality of the current heating area after air purification to obtain indoor air pollution turbidity;

the feedback module is further used for increasing air purification strength and feeding back an ascending instruction to the wall-mounted furnace when the indoor air pollution degree is larger than or equal to a preset first pollution degree threshold value, so that the wall-mounted furnace can ascend heating fire power.

9. A purification device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor, when executing the computer program, carries out the steps of the method according to any one of claims 1 to 4.

10. 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 method of any one of claims 1 to 4.

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