CN117450562A - Wall-mounted furnace heating system and heating control method thereof - Google Patents

Abstract

The application relates to a wall-mounted furnace heating system and a heating control method thereof. The heating control method comprises the steps of obtaining the ambient temperature of each room and the user activity information of each room; under the condition that the user activity exists in the room is identified, if the user is judged to be in a sleep state, determining that the target temperature of the room is a first preset temperature; if the user is judged to be in a non-sleep state, determining that the target temperature of the room is a second preset temperature; if the ambient temperature of any room is less than the corresponding target temperature, driving the water separator-collector to conduct a heating pipeline of the target room and indicating the wall-mounted furnace to work, wherein the target room is a room with the ambient temperature less than the target temperature; if the ambient temperature of each room is greater than or equal to the corresponding target temperature, driving the water separating and collecting device to close the heating pipeline corresponding to each room, and indicating the wall hanging stove to stop working. By adopting the method, the repeated start and stop of the wall-mounted furnace and the heating pipeline in the wall-mounted furnace heating system can be effectively avoided, and the wall-mounted furnace heating system is intelligent.

Description

Wall-mounted furnace heating system and heating control method thereof

Technical Field

The application relates to the technical field of heating control, in particular to a wall-mounted furnace heating system and a heating control method thereof.

Background

In a common wall-mounted furnace heating system, a wall-mounted furnace is used as a heat source, heating hot water is conveyed to the water collector, and then the heating hot water is conveyed to each room through each pipeline of the water collector to supply heat to each room.

For energy saving, room temperature is detected by a room temperature controller in the market, and the electric regulating valve is controlled to be opened and closed by the room temperature controller in a mode of installing the electric regulating valve on the water collecting and distributing device, so that the aim of closing a pipeline valve to realize energy saving is fulfilled.

However, the adoption of the scheme requires users to independently input target temperatures of all rooms, so that the intelligent type wall-mounted furnace is not intelligent enough, and the problem that the overall service life of a wall-mounted furnace heating system is influenced due to the fact that the wall-mounted furnace and a heating pipeline are repeatedly started and stopped is also solved.

Disclosure of Invention

The invention aims to provide a wall-mounted furnace heating system and a heating control method thereof, which can effectively avoid repeated start and stop of a wall-mounted furnace and a heating pipeline in the wall-mounted furnace heating system and are more intelligent.

The technical problems are solved by the following technical scheme:

a heating control method of a wall-mounted boiler heating system comprises the following steps:

Acquiring the ambient temperature of each room and the user activity information of each room; the user activity information includes physiological parameters;

under the condition that the user activity in the room is identified, judging that the user is in a sleep state or a non-sleep state according to the physiological parameters corresponding to the room;

if the room is in the sleep state, determining that the target temperature of the room is a first preset temperature;

if the room is in the non-sleep state, determining that the target temperature of the room is a second preset temperature, wherein the first preset temperature and the second preset temperature are different;

if the ambient temperature of any room is less than the corresponding target temperature, driving the water separator-collector to conduct a heating pipeline of the target room and indicating the wall-mounted furnace to work, wherein the target room is a room with the ambient temperature less than the target temperature;

if the ambient temperature of each room is greater than or equal to the corresponding target temperature, driving the water separating and collecting device to close the heating pipeline corresponding to each room, and indicating the wall hanging stove to stop working.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: in the above embodiment, by acquiring the user activity information of each room, so as to determine whether the user is in the room, further determine the state of the user, and combine the ambient temperature to realize intelligent temperature control, the actual temperature requirement of each room can be more accurately determined, so that the situation of excessive heating or insufficient heating is avoided, meanwhile, the requirement of manual intervention is reduced, the automation degree of the system is improved, and a more comfortable environment is provided for the user. Secondly, under the condition that the ambient temperature of any room is smaller than the corresponding target temperature, the wall-mounted furnace and the heating pipeline are started; and only when the ambient temperature of each room (i.e. all rooms) is greater than or equal to the corresponding target temperature, the wall-mounted furnace and all the heating pipelines are closed, so that the condition that the ambient temperature of a certain room is higher than the corresponding target temperature is avoided, and the ambient temperature of other rooms is not greater than or equal to the target temperature, and all the heating pipelines and the wall-mounted furnace are closed. By adopting the heating control mode, unnecessary starting and stopping can be avoided, so that abrasion to the wall-mounted furnace and a heating pipeline is reduced, and the overall service life of the wall-mounted furnace heating system is prolonged.

In one embodiment, if the ambient temperature of any room is less than the corresponding target temperature, the water separator-collector is driven to conduct the heating pipeline of the target room and instruct the wall-hanging stove to work, including:

if the environmental temperature of any room is smaller than the corresponding target temperature for the first time, comparing the environmental temperature of the target room with the target temperature in a first preset time period;

if the ambient temperature of the target room is continuously smaller than the corresponding target temperature in the first preset time period, the water separator-collector is driven to conduct a heating pipeline of the target room, and the wall-mounted boiler is instructed to work.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: by setting the first preset time period, frequent starting of the wall hanging stove and the heating pipeline can be avoided. If the ambient temperature of a room is below the target temperature for a short period of time, the system will not activate the wall hanging stove and heating pipe. Thus, unnecessary energy consumption and equipment abrasion can be reduced, and the service lives of the wall-mounted furnace and the heating pipeline can be prolonged. If the ambient temperature of a room is below the target temperature for a long period of time, the system will activate the wall hanging stove and heating plumbing to ensure that the indoor temperature reaches a comfortable level. The limitation setting of 'first time' further avoids frequently starting and stopping heating equipment, reduces the waste of energy and the wearing and tearing of equipment.

In one embodiment, if the ambient temperature of any room is less than the corresponding target temperature, the water separator-collector is driven to conduct the heating pipeline of the target room and instruct the wall-hanging stove to work, and the method further comprises:

if the environmental temperature of any room is less than the corresponding target temperature, the water separator-collector is driven to conduct the heating pipeline of the target room, and the wall-mounted furnace is instructed to work.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: compared with the processing mode when the environmental temperature of the target room is lower than the target temperature for the first time, the corresponding heating pipeline of the target room can be directly conducted and the wall-mounted furnace is kept in the working state when the environmental temperature of the target room is not the first time, so that the time delay of waiting for starting the heating system again is avoided, the response speed of the heating system is improved, and the target room can reach the target temperature more quickly.

In one embodiment, if the ambient temperature of each room is equal to or greater than the corresponding target temperature, the water separator-collector is driven to close the heating pipeline corresponding to each room, and the wall-mounted furnace is instructed to stop working, including:

if the environmental temperature of each room is larger than or equal to the corresponding target temperature for the first time, comparing the environmental temperature of each room with the target temperature in a second preset time period;

If the ambient temperature of each room is greater than or equal to the corresponding target temperature in the second preset time period, driving the water dividing and collecting device to close the heating pipeline corresponding to each room, and indicating the wall-mounted furnace to stop working.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: through the condition that the ambient temperature of each room is larger than or equal to the corresponding target temperature and the setting of the second preset time, the situation that the heating system is closed due to short-time fluctuation of the room temperature or unstable heating is avoided to be triggered by mistake is avoided, so that the heating equipment is prevented from being started and stopped frequently, the waste of energy sources and the abrasion of the equipment are reduced, and the efficiency and the service life of the heating system are improved.

In one embodiment, if the ambient temperature of each room is equal to or greater than the corresponding target temperature, the water separator-collector is driven to close the heating pipeline corresponding to each room, and the wall-mounted furnace is instructed to stop working, and the method further comprises:

if the ambient temperature of each room is not equal to or higher than the corresponding target temperature for the first time, the water separator-collector is driven to close the heating pipeline corresponding to each room.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: only the water dividing and collecting device is driven to close the heating pipeline corresponding to the room with the target temperature, and the wall hanging stove is kept in a working state, so that the rest rooms which do not reach the target temperature continue to be heated, energy sources can be saved, comfort level can be improved, accurate control can be realized, and flexibility can be improved.

In one embodiment, the method further comprises:

and under the condition that no user activity exists in each room, determining that the user is in an outgoing state, and determining that the target temperature of each room is a third preset temperature, wherein the third preset temperature is different from the first preset temperature and the second preset temperature.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: when it is recognized that no user activity exists in each room, the system can determine that the user is in an outgoing state and set the target temperature of each room to a third preset temperature, so as to save energy and provide a proper indoor temperature.

In one embodiment, the physiological parameter is a parameter collected by the wearable device, and the step of identifying that no user activity is present in each room comprises:

if the wearable device is not connected to each room in the third preset time period, judging that no user activity exists in each room.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: a specific embodiment is provided for enabling the determination of whether there is user activity in the room.

In one embodiment, the method further comprises:

and if the fact that the user activities do not exist in all the rooms is continuously judged in the fourth preset time period, entering a low-power-consumption working mode.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: the heating system is in a low-power-consumption working mode in the long-term outgoing state by detecting whether the user is in the outgoing state for a long time or not, so that the power consumption is further reduced.

In one embodiment, before the step of determining that the user is in the sleep state or the non-sleep state according to the physiological parameter corresponding to the room, the method further includes:

judging whether the wearable equipment is worn normally or not according to the physiological parameters;

if the wearing is judged to be normal, the step of judging whether the user is in a sleep state or not according to the physiological parameters corresponding to the room under the condition that the user activity exists in the room is carried out;

if the wearing is abnormal, determining that the target temperature of the room is the second preset temperature.

Compared with the background technology, the heating control method of the wall-mounted boiler heating system has the following beneficial effects: by judging the wearing state of the wearable equipment according to the physiological parameters and determining the target temperature of the room according to the wearing state, the system can perform automatic control more intelligently according to the state of the user, and the requirement of manual intervention is reduced; the target temperature of the room can be determined more accurately, the waste of energy sources is avoided, and the energy source utilization efficiency is improved.

A wall-mounted boiler heating system for performing the method of the above embodiment, the system comprising:

the wall-mounted furnace is used for heating each room;

the water dividing and collecting device is arranged on a heating pipeline leading to each room and is communicated with a heating water outlet pipe of the wall-mounted furnace;

the temperature controllers are respectively arranged in different rooms, a first control end of each temperature controller is connected with the wall-mounted boiler, a second control end of each temperature controller is connected with the water collecting and distributing device, and each temperature controller is used for communicating with wearable equipment in the corresponding room.

The specific implementation manner of the wall-mounted boiler heating system in this embodiment corresponds to the heating control method in the foregoing embodiment, and the specific implementation manner and beneficial effects thereof may refer to the description in the foregoing embodiment, which is not repeated herein.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the related art, the drawings that are required to be used in the embodiments or the related technical descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings may be obtained according to the drawings without inventive effort for a person having ordinary skill in the art.

FIG. 1 is an environmental diagram of an application of a heating control method for a wall-mounted boiler heating system in one embodiment;

FIG. 2 is a flow chart of a heating control method of a wall-mounted boiler heating system according to an embodiment;

FIG. 3 is a schematic flow chart of a step of driving the water separator-collector to conduct a heating pipe of a target room and indicating the operation of the wall-hanging stove if the ambient temperature of any room is less than the corresponding target temperature in one embodiment;

fig. 4 is a schematic flow chart of a step of driving the water collector to close the heating pipeline corresponding to each room and indicating the hanging stove to stop working if the ambient temperature of each room is equal to or higher than the corresponding target temperature in one embodiment;

FIG. 5 is a flow chart of a heating control method of a wall-mounted boiler heating system according to another embodiment;

FIG. 6 is a schematic flow chart of a heating control method of a wall-mounted boiler heating system according to another embodiment;

FIG. 7 is a flow chart of a heating control method of a wall-mounted boiler heating system according to still another embodiment;

FIG. 8 is a block diagram of a heating control device according to an embodiment;

fig. 9 is an internal structural diagram of a computer device in one embodiment.

Reference numerals illustrate: 2-hanging stove, 4-diversity water ware, 6-temperature controller, 8-wearable equipment, 10-router, 12-cloud ware, 14-mobile terminal, 30-room.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

The heating control method of the wall-mounted boiler heating system provided by the embodiment of the application can be applied to an application environment shown in fig. 1. Wherein, hanging stove heating system includes hanging stove 2, divides water collector 4 and a plurality of temperature controllers 6 at least. The wall-mounted furnace 2 is used for heating each room 30; the water dividing and collecting device 4 is arranged on a heating pipeline leading to each room 30 and is communicated with a heating water outlet pipe of the wall-mounted furnace 2; the temperature controllers 6 are respectively arranged in different rooms 30, a first control end of each temperature controller 6 is in communication connection with the wall-mounted boiler 2, a second control end of each temperature controller 6 is in communication connection with the water collecting and distributing device 4, and each temperature controller 6 is used for communicating with the wearable equipment 8 in the corresponding room 30. The thermostat 6 provided in each room 30 acquires the ambient temperature of each room 30 and the user activity information of each room 30; the user activity information includes physiological parameters; judging that the user is in a sleep state or a non-sleep state according to the physiological parameters corresponding to the room 30 when the user activity in the room 30 is recognized; if in the sleep state, determining the target temperature of the room 30 as a first preset temperature; if in the non-sleep state, determining the target temperature of the room 30 as a second preset temperature, the first preset temperature being different from the second preset temperature; if the ambient temperature of any room 30 is less than the corresponding target temperature, driving the water separator-collector 4 to conduct a heating pipeline of the target room 30 and indicating the wall-mounted furnace 2 to work, wherein the target room 30 is a room 30 with the ambient temperature less than the target temperature; if the ambient temperature of each room 30 is equal to or higher than the corresponding target temperature, the water separator-collector 4 is driven to close the heating pipeline corresponding to each room 30, and the wall-mounted boiler 2 is instructed to stop working.

In an exemplary embodiment, as shown in fig. 2, a heating control method of a wall-mounted boiler heating system is provided, and an example of application of the method to the wall-mounted boiler heating system in fig. 1 is described, including the following steps S202 to S212. Wherein:

s202, acquiring the ambient temperature of each room and the user activity information of each room; the user activity information includes physiological parameters;

wherein the ambient temperature may refer to an actual temperature in the room, for example, in summer, the ambient temperature may rise to 30 ℃ or higher; in winter, the ambient temperature may drop to 10 ℃ or less. The user activity information may include location information of the user and physiological parameters of the user.

For example, for the acquisition of the ambient temperature of each room, the thermostat provided in each room may be directly acquired from the temperature sensor in each room. The user activity information of each room can acquire the position information of the user and the physiological parameters of the user through the wearable equipment worn on the user body, and acquire the position information of the user, the physiological parameters of the user and the like through communication connection with the temperature controller.

S204, under the condition that the user activity in the room is identified, judging that the user is in a sleep state or a non-sleep state according to the physiological parameters corresponding to the room.

S206, if the room is in the sleep state, determining that the target temperature of the room is the first preset temperature.

S208, if the room is in a non-sleep state, determining that the target temperature of the room is a second preset temperature, wherein the first preset temperature and the second preset temperature are different.

Physiological parameters may include, but are not limited to, physiological indicators of a user's body temperature, heart rate, respiratory rate, activity, etc., which may reflect the user's energy needs and their degree of adaptation to the ambient temperature. The sleep state may be a state in which the user sleeps in a room. The first preset temperature may refer to a temperature set by the system in case it is recognized that there is user activity in the room. This temperature may be to maintain a comfortable sleeping environment if the user is in a sleeping state. . The non-sleep state may refer to an active state in which the user is not in a sleep state, such as reading and working in a room, etc., in which the user's demand for ambient temperature may be different from the sleep state, and thus the system may set a different target temperature. The second preset temperature may refer to a target temperature set upon identifying that the user is in a non-sleep state, which temperature will typically be higher than the first preset temperature to accommodate the higher activity level and energy requirements of the user in the non-sleep state.

For example, in the event that a room is identified as having user activity, it is determined whether the user is asleep by monitoring physiological parameters of the user (e.g., heart rate and respiratory rate). For example, a user may be considered to be asleep at this time when the user's breathing rate is monitored to be about 12-20 times per minute. It should be noted that the above respiratory rate is merely illustrative, and a person skilled in the art may set different parameters according to individual differences to determine whether the user is in a sleep state, which is not limited herein.

And S210, if the ambient temperature of any room is smaller than the corresponding target temperature, driving the water separator-collector to conduct a heating pipeline of the target room, and indicating the wall-mounted furnace to work, wherein the target room is a room with the ambient temperature smaller than the target temperature.

The water collector is equipment for a floor heating system, and can distribute hot water in a heating main pipeline connected with the wall hanging stove to each branch pipe so as to heat each room.

By way of example, by detecting the ambient temperature of each room and comparing with a set target temperature, it is possible to determine which rooms need heating. When the rooms to be heated are judged, the water dividing and collecting device can be driven to introduce the hot water in the main heating pipeline into the heating pipelines of the target rooms. In order to meet the heating demand, the wall-hanging stove needs to be instructed to start working to generate enough hot water to be delivered into the main heating pipeline. For example, assume that there are three rooms in a residence, respectively a living room, a bedroom, and a kitchen. The target temperature was set at 20 ℃. By detection, the ambient temperature in the living room was found to be 18 ℃, the ambient temperature in the bedroom was found to be 17 ℃, and the ambient temperature in the kitchen was found to be 21 ℃. According to the above conditions, it can be judged that the ambient temperature of the living room and the bedroom is lower than the target temperature, and therefore, it is necessary to heat it. At this time, the water separator-collector can be driven to conduct heating pipelines of the living room and the bedroom, and the wall-mounted furnace is instructed to start working so as to meet the heating requirements of the two rooms.

And S212, if the ambient temperature of each room is greater than or equal to the corresponding target temperature, driving the water splitting and collecting device to close the heating pipeline corresponding to each room, and indicating the hanging furnace to stop working.

The ambient temperature of each room is illustratively detected by a temperature sensor or other device. The detected ambient temperature is compared with a set target temperature. If the ambient temperature of each room is equal to or higher than the corresponding target temperature, the water separator-collector can be driven to close the heating pipeline of each room. Because heating is not needed, the wall hanging stove can be instructed to stop working, so that energy and resources are saved. For example, in the above-described residence, the target temperatures for living rooms, bedrooms and kitchens are still 20 ℃. The detection shows that the ambient temperature of the living room is 22 ℃, the ambient temperature of the bedroom is 21 ℃, and the ambient temperature of the kitchen is 23 ℃. According to the above conditions, it can be determined that the ambient temperature of all the rooms is equal to or higher than the corresponding target temperature, so that it is necessary to close the heating pipes of the respective rooms and stop the operation of the wall hanging stove. At this time, the water separator-collector can be driven to close the heating pipelines of the living room, the bedroom and the kitchen, and the wall-mounted furnace is instructed to stop working, so that energy and resources are saved.

In the above embodiment, by acquiring the user activity information of each room, so as to determine whether the user is in the room, further determine the state of the user, and combine the ambient temperature to realize intelligent temperature control, the actual temperature requirement of each room can be more accurately determined, so that the situation of excessive heating or insufficient heating is avoided, meanwhile, the requirement of manual intervention is reduced, the automation degree of the system is improved, and a more comfortable environment is provided for the user. Secondly, under the condition that the ambient temperature of any room is smaller than the corresponding target temperature, the wall-mounted furnace and the heating pipeline are started; and only when the ambient temperature of each room (i.e. all rooms) is greater than or equal to the corresponding target temperature, the wall-mounted furnace and all the heating pipelines are closed, so that the condition that the ambient temperature of a certain room is higher than the corresponding target temperature is avoided, and the ambient temperature of other rooms is not greater than or equal to the target temperature, and all the heating pipelines and the wall-mounted furnace are closed. By adopting the heating control mode, unnecessary starting and stopping can be avoided, so that abrasion to the wall-mounted furnace and a heating pipeline is reduced, and the overall service life of the wall-mounted furnace heating system is prolonged.

In an exemplary embodiment, if the ambient temperature of any room is less than the corresponding target temperature, the water separator-collector is driven to conduct the heating pipeline of the target room, and the wall-hanging stove is instructed to work, including:

s302, if the environmental temperature of any room is smaller than the corresponding target temperature for the first time, comparing the environmental temperature of the target room with the target temperature in the first preset time period.

S304, if the ambient temperature of the target room is continuously smaller than the corresponding target temperature in the first preset time period, driving the water separator-collector to conduct a heating pipeline of the target room, and indicating the wall-mounted furnace to work.

Wherein, "first time" means that the ambient temperature of the target room is less than the target temperature when it is detected for the first time. The first preset time period can be understood as a time range for controlling the starting of the wall-mounted boiler and the heating pipeline in time, so as to avoid false triggering of the wall-mounted boiler heating system to heat the room due to short-time temperature fluctuation in the room.

For example, when it first appears that the ambient temperature of a certain room is less than the corresponding target temperature, this point in time is recorded and a comparison of the ambient temperature of the target room and the target temperature within a first preset period of time is started. For example, assume that the first preset time period is 30 minutes. If the ambient temperature of a room is below the corresponding target temperature at 09:00, the system records this point in time and begins to monitor the ambient temperature of the room. If the ambient temperature of the room is always below the target temperature for the next 30 minutes, the system will consider the room to require heating and activate the wall station and the heating plumbing for the room. The system then continues to monitor the ambient temperature of the room and if the ambient temperature rises above the target temperature, the system shuts down the wall hanging stove and the heating plumbing for the room. The purpose of emphasis on the first time is to avoid frequent starting and stopping of heating equipment and reduce energy waste and equipment abrasion. Without the "first time" limitation, the heating system would start whenever the ambient temperature of the target room is slightly below the target temperature, and then stop when the ambient temperature rises slightly. Such frequent start-stop procedures can result in loss of the heating equipment and waste of energy. Therefore, by limiting the operation of the heating system to be triggered only when the target room ambient temperature is detected to be less than the target temperature for the first time, frequent start and stop of the heating equipment can be effectively avoided, and the efficiency and the service life of the heating system are improved.

In the above embodiment, by setting the first preset time period, frequent starting of the wall hanging stove and the heating pipeline can be avoided. If the ambient temperature of a room is below the target temperature for a short period of time, the system will not activate the wall hanging stove and heating pipe. Thus, unnecessary energy consumption and equipment abrasion can be reduced, and the service lives of the wall-mounted furnace and the heating pipeline can be prolonged. If the ambient temperature of a room is below the target temperature for a long period of time, the system will activate the wall hanging stove and heating plumbing to ensure that the indoor temperature reaches a comfortable level. The limitation setting of 'first time' further avoids frequently starting and stopping heating equipment, reduces the waste of energy and the wearing and tearing of equipment.

In one embodiment, as shown in fig. 3, if the ambient temperature of any room is less than the corresponding target temperature, the water separator-collector is driven to conduct the heating pipeline of the target room and instruct the wall-hanging stove to work, and the method further includes:

s306, if the environmental temperature of any room is not smaller than the corresponding target temperature for the first time, driving the water separator-collector to conduct a heating pipeline of the target room, and indicating the wall-mounted furnace to work.

For example, when the ambient temperature of any room which does not occur for the first time is less than the corresponding target temperature, the water separator-collector can be directly driven to conduct the heating pipeline of the target room, and the wall-mounted boiler is instructed to work. The system is still in the heating process in the previous heating period, and in the process, the wall-mounted furnace is always in the working state, if the environmental temperature of a certain room is smaller than the corresponding target temperature at the moment, the wall-mounted furnace can be heated to improve the target temperature of the room only by conducting the heating pipeline corresponding to the certain room and keeping the wall-mounted furnace in the working state. For example, the above-described house including three rooms of living room, bedroom, and kitchen is still described as an example: through detection, the ambient temperature of the living room is found to be 18 ℃, and the set target temperature of the living room is found to be 20 ℃; the ambient temperature of the bedroom is 22 ℃, and the set target temperature of the bedroom is 22 ℃; the ambient temperature of the kitchen is 23 ℃, and the target temperature set in the kitchen is 23 ℃. The first time that the ambient temperature of any room is smaller than the corresponding target temperature, the target room is the living room, the ambient temperature of the living room is still smaller than the corresponding target temperature in the first preset time period, and under the condition, a heating pipeline of the living room is conducted and the wall hanging furnace is started to work, so that heating of the living room can be achieved. Before the living room is heated to the target temperature of 20 ℃, the ambient temperature of the bedroom, the kitchen and even the living room which is heating is reduced due to the influence of outdoor weather, and the ambient temperature of any room is not smaller than the corresponding target temperature for the first time. Because the wall-mounted boiler is always in a working state, the water separator-collector is directly driven to conduct heating pipelines corresponding to bedrooms and kitchens, and heating of the bedrooms and the kitchens can be achieved. Further, if the environmental temperature of the living room being heated is also reduced, the power of the wall-mounted furnace can be increased according to actual needs, so that the living room, the bedroom and the kitchen can reach respective corresponding target temperatures under the influence of outdoor weather.

In the above embodiment, compared with the processing mode when the ambient temperature of the target room is lower than the target temperature for the first time, the corresponding heating pipeline of the target room can be directly conducted and the wall-mounted furnace is kept in the working state when the ambient temperature of the target room is not the first time, so that the time delay of waiting for starting the heating system again is avoided, the response speed of the heating system is improved, and the target room can reach the target temperature more quickly.

In an exemplary embodiment, as shown in fig. 4, if the ambient temperature of each room is equal to or greater than the corresponding target temperature, the water separator-collector is driven to close the heating pipeline corresponding to each room, and the wall-hanging stove is instructed to stop working, including:

s402, if the environmental temperature of each room is larger than or equal to the corresponding target temperature for the first time, comparing the environmental temperature of each room with the target temperature in a second preset time period.

S404, if the ambient temperature of each room is equal to or higher than the corresponding target temperature in the second preset time period, driving the water separator-collector to close the heating pipeline corresponding to each room, and indicating the hanging furnace to stop working.

Wherein, "first time" means that the ambient temperature of each room is detected to be greater than or equal to the corresponding target temperature for the first time. The second preset time period can be understood as a time range of controlling the closing of the wall hanging stove and the heating pipeline in time, namely, a period of time after the environmental temperature of each room is larger than or equal to the corresponding target temperature for the first time, so as to avoid the heating stop of the room caused by the fact that the wall hanging stove is closed by false triggering due to short-time temperature fluctuation in the room.

For example, when the ambient temperature of each room is greater than or equal to the corresponding target temperature for the first time, the system may further compare the ambient temperature of each room to the target temperature for a second preset period of time to determine whether the heating system needs to continue to operate. If the ambient temperature of each room is still greater than or equal to the corresponding target temperature within the second preset time period, then the whole heating system is judged to have reached the steady state, and heating is not required to be continued. At the moment, the water separating and collecting devices are driven to close the heating pipelines corresponding to the rooms, and the wall hanging stove is instructed to stop working. For example, taking the residence in the foregoing embodiment as an example, in the heating process, when the living room, the bedroom and the kitchen all reach the corresponding target temperatures for the first time, that is, the environmental temperature of each room is greater than or equal to the corresponding target temperature for the first time, by continuously detecting the environmental temperatures of the living room, the bedroom and the kitchen in the second preset time period, if the environmental temperature of each room is always greater than or equal to the corresponding target temperature in the second preset time period, it is indicated that the heating is stable at this time, and the room temperature is raised stably, the water separator-collector can be driven to close the heating pipeline corresponding to each room, and the hanging stove is instructed to stop working.

In the above embodiment, by first occurrence of the condition that the ambient temperature of each room is greater than or equal to the corresponding target temperature and setting of the second preset time, the shutdown of the heating system due to short-time fluctuation of the room temperature or unstable heating is avoided, so that the frequent start and stop of the heating equipment is avoided, the waste of energy sources and the abrasion of the equipment are reduced, and the efficiency and the service life of the heating system are improved.

In an exemplary embodiment, as shown in fig. 4, if the ambient temperature of each room is equal to or greater than the corresponding target temperature, the water separator-collector is driven to close the heating pipeline corresponding to each room, and the wall-hanging stove is instructed to stop working, including:

and S406, if the environmental temperature of each room is not equal to or higher than the corresponding target temperature for the first time, driving the water separator-collector to close the heating pipeline corresponding to each room.

Wherein, the non-first occurrence of the ambient temperature of each room being greater than or equal to the corresponding target temperature may refer to the ambient temperature of any number of rooms being greater than or equal to the corresponding target temperature. For example, in the above-described residence, when the ambient temperatures of the living room and the kitchen are equal to or higher than the corresponding target temperatures, and the ambient temperature of the bedroom is still lower than the corresponding ambient temperature, that is, when there is a room which does not reach the corresponding target temperature, it is considered that "the ambient temperature of each room is equal to or higher than the corresponding ambient temperature without first occurrence".

In the heating process, when a room which does not reach the corresponding target temperature still exists, even if the environmental temperature of a part of rooms is larger than or equal to the corresponding target temperature, only the water dividing and collecting device is driven to close the heating pipeline corresponding to the part of rooms, and the wall hanging stove is kept in a working state, so that the rest rooms which do not reach the corresponding target temperature continue to be heated until the environmental temperature of the rooms is larger than or equal to the corresponding target temperature. In the process, if the ambient temperature of the part of rooms is smaller than the corresponding target temperature again, the wall-mounted furnace is still in a working state, so that the part of rooms can be quickly heated again.

In the embodiment, only the water separator-collector is driven to close the heating pipeline corresponding to the room with the target temperature, and the wall-mounted furnace is kept in the working state, so that the rest rooms with the target temperature are continuously heated, and the energy sources can be saved, the comfort level can be improved, the accurate control can be realized, and the flexibility can be improved.

In an exemplary embodiment, as shown in fig. 5, the method further comprises:

s502, under the condition that no user activity exists in each room, determining that the user is in an outgoing state, and determining that the target temperature of each room is a third preset temperature, wherein the third preset temperature is different from the first preset temperature and the second preset temperature.

The third preset temperature is different from the first preset temperature and the second preset temperature, namely the third preset temperature is suitable for a time period when the user goes out.

By setting the target temperature of each room to the third preset temperature, the operation intensity of the heating system can be reduced when the user goes out, for example, to save energy and improve the efficiency of the heating system. The waste of keeping high temperature under the condition of no user activity is avoided, and the temperature can be raised at proper time before the user returns home, so that a comfortable indoor environment is provided.

In the above embodiment, when it is recognized that no user activity exists in each room, the system may determine that the user is in an outgoing state, and set the target temperature of each room to a third preset temperature, so as to save energy and provide a suitable indoor temperature.

In an exemplary embodiment, as shown in fig. 6, the physiological parameter is a parameter collected by the wearable device, and the step of identifying that no user activity exists in each room includes:

s602, if none of the rooms is connected to the wearable device in the third preset period, determining that no user activity exists in each room.

The wearable device may generally refer to an electronic device that a user may carry with him, such as a smart watch, a smart bracelet, a smart necklace, etc., where the device may record the behavior and physiological parameters of the user and transmit the parameters to the system through a wireless connection. The third preset time period may be understood as a time range in which the system determines whether the user is in an outgoing state. The selection of the third preset time period can be adjusted according to actual requirements. It may be a fixed time interval, such as 30 minutes, 1 hour, etc., over a period of time, or may be a period of time dynamically calculated according to the user's lifestyle or activity pattern. For example, if the user typically goes out of work at 7 o ' clock in the morning, the third preset time period may be set to between 6 o ' clock and 8 o ' clock in the morning.

For example, in a scenario where the user is originally in a room and the wearable device worn on the hand is in a connected state, the time period may be dynamically calculated by setting a third preset time period, for example, 30 minutes, 1 hour, etc., or according to the life habit or activity pattern of the user; and monitoring the connection status of the wearable devices in the respective rooms, such as by providing corresponding monitoring modules in the system or communicating with the wearable devices. And in a third preset time period, the connection state of the wearable equipment in each room is recorded by monitoring the connection state of the wearable equipment in a timing or real-time manner. And when the third preset time period is over, if the wearable devices in all the rooms are not connected, judging that no user activity exists in each room.

In the foregoing embodiment, a specific implementation manner is provided for implementing whether a user activity exists in a room.

In one exemplary embodiment, as shown in fig. 6, the method further comprises:

and S604, if the fact that the user activity does not exist in each room is continuously judged in the fourth preset time period, entering a low-power-consumption working mode.

Among other things, a low power mode may refer to shutting down some unnecessary functions and equipment to reduce energy consumption and carbon emissions while maintaining the basic functions of the system in normal operation. For example, control accuracy may be reduced, and the temperature control range may be widened to reduce the run time and power consumption of the system.

After the target temperature is determined to be the third preset temperature, the fourth preset time period is further set, and in the fourth preset time period, it is continuously judged that no user activity exists in each room, and the fact that the user is in a long-term outgoing state at this time is indicated, the heating system enters a low-power-consumption working mode to reduce power consumption, and further, in order to ensure safety, a gas valve closing instruction can be issued to avoid gas leakage.

In the embodiment, the power consumption is further reduced by detecting whether the user is in the outgoing state for a long time and enabling the heating system to be in the low-power-consumption working mode as a whole when the user is in the outgoing state for a long time.

In an exemplary embodiment, as shown in fig. 7, before the step of determining that the user is in a sleep state or a non-sleep state according to the physiological parameters corresponding to the room, the method further includes:

s702, judging whether the wearable device is worn normally according to the physiological parameters.

Whether the wearable device is worn normally may refer to whether the wearable device is connected to or worn by the body of the user normally, for example, whether the tightness of the watchband is appropriate.

For example, if the wearable device monitors heart rate data of the user, but the data is abnormal or not steady, it may be considered that the wearable device may not be worn normally.

If the wearing is judged to be normal, step 704 is entered to judge whether the user is in a sleep state or not according to the physiological parameters corresponding to the room when the user activity is recognized to exist in the room.

For example, if the wearable device is judged to be worn normally, the method enters a step of judging that the user is in a sleep state or a non-sleep state according to the physiological parameters corresponding to the room under the condition that the user activity is recognized to exist in the room, so as to determine the target temperature of the room.

S706, if the wearing is abnormal, determining that the target temperature of the room is the second preset temperature.

For example, if it is determined that the wearable device is not wearing properly, the target temperature of the room is determined to be a second preset temperature. The second preset temperature may be set to a temperature slightly higher than the first preset temperature to avoid an excessively low temperature due to the wearable device not being worn normally.

In the embodiment, by judging the wearing state of the wearable equipment according to the physiological parameters and determining the target temperature of the room according to the wearing state, the system can more intelligently perform automatic control according to the state of the user, and the requirement of manual intervention is reduced; the target temperature of the room can be determined more accurately, the waste of energy sources is avoided, and the energy source utilization efficiency is improved.

In one exemplary embodiment, as shown in fig. 1, a wall-mounted boiler heating system is provided, the system comprising:

the wall-mounted furnace 2, wherein the wall-mounted furnace 2 is used for heating each room 30;

the water dividing and collecting device 4 is arranged on a heating pipeline leading to each room 30 and is communicated with a heating water outlet pipe of the wall-mounted furnace 2;

the temperature controllers 6 are respectively arranged in different rooms 30, a first control end of each temperature controller 6 is connected with the wall-mounted boiler 2, a second control end of each temperature controller 6 is connected with the water collecting and distributing device 4, and each temperature controller 6 is used for communicating with the wearable equipment 8 in the corresponding room 30.

The specific implementation manner of the wall-mounted boiler heating system in this embodiment corresponds to the heating control method in the foregoing embodiment, and the specific implementation manner and beneficial effects thereof may refer to the description in the foregoing embodiment, which is not repeated herein. It should be noted that, as shown in fig. 1, the wall-mounted boiler heating system further includes a router 10 and a cloud server 12, so as to send the operation state and operation parameters of the heating system to a mobile terminal 14 for a user or a maintenance person to check, thereby realizing real-time monitoring of the heating system.

It should be understood that, although the steps in the flowcharts related to the embodiments described above are sequentially shown as indicated by arrows, these steps are not necessarily sequentially performed in the order indicated by the arrows. The steps are not strictly limited to the order of execution unless explicitly recited herein, and the steps may be executed in other orders. Moreover, at least some of the steps in the flowcharts described in the above embodiments may include a plurality of steps or a plurality of stages, which are not necessarily performed at the same time, but may be performed at different times, and the order of the steps or stages is not necessarily performed sequentially, but may be performed alternately or alternately with at least some of the other steps or stages.

Based on the same inventive concept, the embodiment of the application also provides a heating control device for realizing the heating control method. The implementation of the solution provided by the apparatus is similar to that described in the above method, so the specific limitation of one or more embodiments of the heating control apparatus provided below may be referred to the limitation of the heating control method hereinabove, and will not be repeated herein.

In one exemplary embodiment, as shown in fig. 8, there is provided a heating control apparatus including:

an information acquisition module 802, configured to acquire an ambient temperature of each room and user activity information of each room; the user activity information includes physiological parameters.

The identifying module 804 is configured to determine that the user is in a sleep state or a non-sleep state according to the physiological parameter corresponding to the room when it is identified that the user activity exists in the room;

a first temperature determining module 806, configured to determine, in a case of being in a sleep state, that a target temperature of the room is a first preset temperature;

a second temperature determining module 808, configured to determine, when the room is in a non-sleep state, that the target temperature of the room is a second preset temperature, where the first preset temperature and the second preset temperature are different;

The first control module 810 is configured to drive the water separator-collector to conduct a heating pipe of a target room and instruct the wall-mounted boiler to operate when the ambient temperature of any room is less than the corresponding target temperature, where the target room is a room with the ambient temperature less than the target temperature;

and the second control module 812 is configured to drive the water separator-collector to close the heating pipes corresponding to each room and instruct the wall-mounted boiler to stop working when the ambient temperature of each room is equal to or higher than the corresponding target temperature.

In an exemplary embodiment, the first control module 810 includes:

the first comparison unit is used for comparing the ambient temperature of the target room with the target temperature in a first preset time period when the ambient temperature of any room is smaller than the corresponding target temperature for the first time;

the first control unit is used for driving the water separator-collector to conduct a heating pipeline of the target room and indicating the wall-mounted furnace to work under the condition that the ambient temperature of the target room is continuously smaller than the corresponding target temperature in a first preset time period.

In an exemplary embodiment, the first control module 810 further includes:

and the second control unit is used for driving the water separator-collector to conduct a heating pipeline of the target room and indicating the wall-mounted furnace to work under the condition that the ambient temperature of any room is less than the corresponding target temperature for the first time.

In an exemplary embodiment, the second control module 812 includes:

the second comparison unit is used for comparing the ambient temperature of each room with the target temperature in a second preset time period under the condition that the ambient temperature of each room is larger than or equal to the corresponding target temperature for the first time;

and the third control unit is used for driving the water dividing and collecting device to close the heating pipelines corresponding to the rooms and indicating the wall hanging furnace to stop working under the condition that the ambient temperature of each room is more than or equal to the corresponding target temperature in the second preset time period.

In an exemplary embodiment, the second control module 812 further includes:

and the fourth control unit is used for driving the water separator-collector to close the heating pipeline corresponding to each room under the condition that the ambient temperature of each room is not equal to or higher than the corresponding target temperature for the first time.

In an exemplary embodiment, the heating control device further includes:

the third temperature determining module is used for determining that the user is in an outgoing state under the condition that no user activity exists in each room, and determining that the target temperature of each room is a third preset temperature, wherein the third preset temperature is different from the first preset temperature and the second preset temperature.

In an exemplary embodiment, the third temperature determining module includes:

and the first user judging unit is used for judging that no user activity exists in each room under the condition that no wearable device is connected in each room in the third preset time period.

In an exemplary embodiment, the third temperature determining module includes:

and the second user judging unit is used for entering a low-power-consumption working mode under the condition that the user activity does not exist in each room in the fourth preset time period.

In an exemplary embodiment, the heating control device further includes:

the normal wearing judging module is used for judging whether the wearable equipment is worn normally or not according to the physiological parameters;

the first action module is used for entering a step of judging whether the user is in a sleep state or not according to the physiological parameters corresponding to the room under the condition that the user activity is recognized in the room under the condition that the wearing is judged to be normal;

the second action module is used for determining that the target temperature of the room is a second preset temperature under the condition that the wearing is abnormal.

The respective modules in the heating control apparatus described above may be implemented in whole or in part by software, hardware, and combinations thereof. The above modules may be embedded in hardware or may be independent of a processor in the computer device, or may be stored in software in a memory in the computer device, so that the processor may call and execute operations corresponding to the above modules.

In one exemplary embodiment, a computer device is provided, which may be a system, the internal structure of which may be as shown in fig. 9. The computer device includes a processor, a memory, an Input/Output interface (I/O) and a communication interface. The processor, the memory and the input/output interface are connected through a system bus, and the communication interface is connected to the system bus through the input/output interface. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of computer devices is used to store ambient temperature data and target temperature data for each room and user activity information. The input/output interface of the computer device is used to exchange information between the processor and the external device. The communication interface of the computer device is used for communicating with an external terminal through a network connection. The computer program, when executed by a processor, implements a heating control method.

It will be appreciated by those skilled in the art that the structure shown in fig. 9 is merely a block diagram of a portion of the structure associated with the present application and is not limiting of the computer device to which the present application applies, and that a particular computer device may include more or fewer components than shown, or may combine some of the components, or have a different arrangement of components.

In an exemplary embodiment, a computer device is provided, comprising a memory and a processor, the memory having stored therein a computer program, the processor performing the steps of the method embodiments described above when the computer program is executed.

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:

in one embodiment, a computer program product is provided comprising a computer program which, when executed by a processor, performs the steps of:

it should be noted that, the user activity information (including, but not limited to, user equipment information, user personal information, etc.) and the data (including, but not limited to, data for analysis, stored data, presented data, etc.) referred to in the present application are information and data authorized by the user or sufficiently authorized by each party, and the collection, use, and processing of the related data are required to meet the related regulations.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, database, or other medium used in the various embodiments provided herein may include at least one of non-volatile and volatile memory. The nonvolatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, high density embedded nonvolatile Memory, resistive random access Memory (ReRAM), magnetic random access Memory (Magnetoresistive Random Access Memory, MRAM), ferroelectric Memory (Ferroelectric Random Access Memory, FRAM), phase change Memory (Phase Change Memory, PCM), graphene Memory, and the like. Volatile memory can include random access memory (Random Access Memory, RAM) or external cache memory, and the like. By way of illustration, and not limitation, RAM can be in the form of a variety of forms, such as static random access memory (Static Random Access Memory, SRAM) or dynamic random access memory (Dynamic Random Access Memory, DRAM), and the like. The databases referred to in the various embodiments provided herein may include at least one of relational databases and non-relational databases. The non-relational database may include, but is not limited to, a blockchain-based distributed database, and the like. The processors referred to in the embodiments provided herein may be general purpose processors, central processing units, graphics processors, digital signal processors, programmable logic units, quantum computing-based data processing logic units, etc., without being limited thereto.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples only represent a few embodiments of the present application, which are described in more detail and are not to be construed as limiting the scope of the present application. It should be noted that it would be apparent to those skilled in the art that various modifications and improvements could be made without departing from the spirit of the present application, which would be within the scope of the present application. Accordingly, the scope of protection of the present application shall be subject to the appended claims.

Claims (10)

1. A heating control method of a wall-mounted boiler heating system, the method comprising:

acquiring the ambient temperature of each room and the user activity information of each room; the user activity information includes physiological parameters;

under the condition that the user activity in the room is identified, judging that the user is in a sleep state or a non-sleep state according to the physiological parameters corresponding to the room;

If the room is in a sleep state, determining that the target temperature of the room is a first preset temperature;

if the room is in a non-sleep state, determining that the target temperature of the room is a second preset temperature, wherein the first preset temperature and the second preset temperature are different;

if the ambient temperature of any room is smaller than the corresponding target temperature, driving the water separator-collector to conduct a heating pipeline of the target room and indicating the wall-mounted furnace to work, wherein the target room is a room with the ambient temperature smaller than the target temperature;

if the ambient temperature of each room is greater than or equal to the corresponding target temperature, driving the water collector to close the heating pipeline corresponding to each room, and indicating the wall hanging stove to stop working.

2. The method according to claim 1, wherein if the ambient temperature of any room is less than the corresponding target temperature, driving the water separator-collector to conduct the heating pipe of the target room and indicating the wall-hanging stove to operate, comprising:

if the environmental temperature of any room is smaller than the corresponding target temperature for the first time, comparing the environmental temperature of the target room with the target temperature in a first preset time period;

if the ambient temperature of the target room is continuously smaller than the corresponding target temperature in the first preset time period, the water separator-collector is driven to conduct a heating pipeline of the target room, and the wall-mounted boiler is instructed to work.

3. The method according to claim 2, wherein if the ambient temperature of any room is less than the corresponding target temperature, driving the water separator-collector to conduct the heating pipe of the target room and indicating the wall-hanging stove to operate, further comprising:

if the environmental temperature of any room is less than the corresponding target temperature, the water separator-collector is driven to conduct the heating pipeline of the target room, and the wall-mounted furnace is instructed to work.

4. The method of claim 1, wherein if the ambient temperature of each room is equal to or higher than the corresponding target temperature, driving the water separator to close the heating pipes corresponding to each room and indicating the hanging stove to stop working, comprises:

if the environmental temperature of each room is larger than or equal to the corresponding target temperature for the first time, comparing the environmental temperature of each room with the target temperature in a second preset time period;

if the ambient temperature of each room is greater than or equal to the corresponding target temperature in the second preset time period, driving the water diversity device to close the heating pipeline corresponding to each room, and indicating the wall hanging stove to stop working.

5. The method of claim 4, wherein if the ambient temperature of each room is equal to or higher than the corresponding target temperature, driving the water separator to close the heating pipes corresponding to each room and indicating the hanging stove to stop working, further comprising:

And if the environmental temperature of each room is not equal to or higher than the corresponding target temperature for the first time, driving the water diversion device to close the heating pipeline corresponding to each room.

6. The method according to claim 1, wherein the method further comprises:

and under the condition that no user activity exists in each room, determining that the user is in an outgoing state, and determining that the target temperature of each room is a third preset temperature, wherein the third preset temperature is different from the first preset temperature and the second preset temperature.

7. The method of claim 6, wherein the physiological parameter is a parameter collected by a wearable device, and wherein the step of identifying that no user activity is present in each room comprises:

if the wearable device is not connected to each room in the third preset time period, judging that no user activity exists in each room.

8. The method of claim 7, wherein the method further comprises:

and if the fact that the user activities do not exist in all the rooms is continuously judged in the fourth preset time period, entering a low-power-consumption working mode.

9. The method of claim 8, wherein the step of determining whether the user is in a sleep state or a non-sleep state according to the physiological parameter corresponding to the room further comprises:

Judging whether the wearable equipment is worn normally or not according to the physiological parameters;

if the wearing is judged to be normal, the step of judging that the user is in a sleep state or a non-sleep state according to the physiological parameters corresponding to the room under the condition that the user activity in the room is recognized;

if the wearing is abnormal, determining that the target temperature of the room is a second preset temperature.

10. A wall-mounted boiler heating system for performing the method of any of claims 1-9, the system comprising:

the wall-mounted furnace (2), wherein the wall-mounted furnace (2) is used for heating each room (30);

the water dividing and collecting device (4) is arranged on a heating pipeline leading to each room (30) and is communicated with a heating water outlet pipe of the wall-mounted furnace (2);

the intelligent water distribution device comprises a plurality of temperature controllers (6), wherein the temperature controllers (6) are respectively arranged in different rooms (30), a first control end of each temperature controller (6) is connected with the wall-mounted boiler (2), a second control end of each temperature controller (6) is connected with the water distribution device (4), and each temperature controller (6) is used for communicating with wearable equipment (8) in the corresponding room (30).