KR20220082569A - Control mehod for ventilation device using air monitor and ventilation device - Google Patents

Abstract

The control method of a ventilation device using an air monitor according to an embodiment of the present invention is a control method of a ventilation device in which the air volume can be adjusted to F1 to FN. a user access determination step of determining whether a user is present, and determining an air volume of the ventilation device according to the presence of the user; an occupant's sleep entry step of determining the air volume of the ventilation device as F1 for a time T1 when a user is present in the room and a change in the indoor illuminance value is detected in the user access determination step; and when a user is present in the room in the step of entering the occupant's sleep and the time T1 elapses after a change in the indoor illuminance value is sensed to decrease, the air volume of the ventilation device is determined according to the carbon dioxide concentration measured by the air monitor. may include; where F1<F2<...<FN, N is 3 or more, FN is the maximum air volume that the ventilation device can drive, F1 is the preset minimum air volume, and the number becomes larger. The air volume increases proportionally.

Description

Control method and ventilation device of ventilation device using air monitor

The present invention relates to a method for controlling a ventilation device using an air monitor and a ventilation device for performing the control method.

Indoor air quality affects the occupants in the room, and especially when the occupants are sleeping, it can affect the quality of a good night's sleep. In order to maintain good indoor air quality, the ventilation device must be continuously driven. However, when the user is in a sleeping state, the ventilation device cannot be manually controlled. Therefore, there is a need for an invention that automatically controls the air quality. .

Also, when the user is in a light sleep, it is difficult to fall asleep deeply due to the noise generated by the operation of the ventilation device. may be affected by noise.

In addition, in a deep sleep state, the concentration of carbon dioxide affects the quality of sleep rather than the temperature or noise of the air, and when the concentration of carbon dioxide is too high, the user may feel stuffy and difficult to fall asleep. Ventilation device operation should be controlled taking all carbon dioxide concentration into consideration.

In order to solve the above problems, control of the ventilation device using an air monitor that automatically controls the air volume of the ventilation device according to the state of the user in the room by determining whether a user is in the room, determining whether to enter a bed, and determining whether to enter a deep sleep It is intended to provide a method and a ventilation device.

The control method of a ventilation device using an air monitor according to an embodiment of the present invention is a control method of a ventilation device in which the air volume can be adjusted to F1 to FN. a user access determination step of determining whether a user is present, and determining an air volume of the ventilation device according to the presence of the user; an occupant's sleep entry step of determining the air volume of the ventilation device as F1 for a time T1 when a user is present in the room and a change in the indoor illuminance value is detected in the user access determination step; and when the T1 time elapses after a change in the indoor illuminance value is detected in the occupant sleep entry step, the occupant deep sleep step of determining the air volume of the ventilation device according to the carbon dioxide concentration measured by the air monitor; may include At this time, F1<F2<...<FN, N is 3 or more, FN is the maximum air volume that the ventilation device can drive, F1 is the preset minimum air volume, and as the number increases, the air volume increases proportionally.

Also, according to an embodiment of the present invention, a change in which the current measured value of the indoor illuminance value is higher than the previous measured value is detected or the occupant's deep sleep is detected while the air volume of the ventilation device is operating at F1 in the occupant's sleep entry step The method may further include a occupant sleep release step of returning to the user access determination step when a change in which the current measured value of the indoor illuminance value is higher than the previous measured value is detected within T2 time from entering the step.

According to an embodiment of the present invention, when a change in which the current measured value of the indoor illuminance value is higher than the previous measured value is detected after more than T2 time has elapsed from the time the occupant enters the deep sleep phase, the air volume of the ventilation device is set to FN It may further include a wake-up step of the occupant to determine.

Specifically, in the user access determination step according to an embodiment of the present invention, the current measured value of the indoor illuminance value is measured to be higher than the previous measured value by a predetermined value or more, and the current measured value of the carbon dioxide concentration is measured to be higher than the previous measured occupancy In the state, ventilation is performed according to the air volume of the ventilation device set by the user, and in the absence state in which the current measured value of the indoor illuminance value is less than or equal to the previous measured value, or the current measured value of the carbon dioxide concentration is measured to be less than or equal to the previous measured value, the It is possible to determine the air volume of the ventilation device according to the current measured value of the carbon dioxide concentration.

In addition, in the user access determination step, in the absence state, when the carbon dioxide concentration measured by the air monitor is less than the first reference value, the ventilation device is turned off, and the carbon dioxide concentration measured by the air monitor is greater than or equal to the first reference value In this case, the ventilation device may be driven at an air volume FN. Since there is no user, the air quality can be quickly restored by determining the air volume of the ventilation device according to the measured air quality without considering the noise of the ventilation device.

In the occupant deep sleep step according to an embodiment of the present invention, the air volume of the ventilation device may be determined in proportion to the carbon dioxide concentration measured by the air monitor. The air volume of the ventilation device is determined by F1 to FM, where M is 2≤M<N. In order not to affect the occupant's sound sleep, the ventilation device does not operate above the maximum or a certain amount of air flow, and the ventilation device is controlled based on the concentration of carbon dioxide, which is an important factor for deep sleep, to improve the user experience and promote rapid air quality recovery. .

As another aspect of the present invention, in the ventilation device using the air monitor according to an embodiment of the present invention, the air volume can be adjusted to F1 to FN, in this case, F1<F2<...<FN, and N is 3 or more , where FN is the maximum air volume that the ventilation device can drive, F1 is a preset minimum air volume, and a ventilation device configured to proportionally increase the air volume as the number increases,

an air monitor that measures indoor air quality information including indoor illuminance value and carbon dioxide concentration in real time; and a control unit that determines the air volume of the ventilation device according to the indoor air quality information measured by the air monitor, wherein the control unit determines whether a user is in the room according to the carbon dioxide concentration and the indoor illuminance value measured by the air monitor And, a user access determination module for determining the air volume of the ventilation device according to the presence of the user; an occupant bedtime entry determination module that determines, when it is determined by the user access determination module that a user exists in the room, that a decrease in the indoor illuminance value is detected, determines the air volume of the ventilation device as F1 for a time T1; and when it is determined by the user access determination module that a user exists in the room, when the T1 time has elapsed after a change in the indoor illuminance value is sensed to decrease, the ventilation device according to the carbon dioxide concentration measured by the air monitor occupant deep sleep determination module to determine the air volume of may include

According to an embodiment of the present invention, the control unit may include: a change in which the current measured value of the indoor illuminance value is higher than the previous measured value while operating at the air volume F1 of the ventilation device determined by the occupant's bedtime determination module; or a change in which the current measured value of the indoor illuminance value is measured to be higher than the previous measured value within T2 time during operation with the air volume of the ventilation device determined by the occupant deep sleep determination module It may further include; a occupant sleep release determination module that drives to determine the air volume of the ventilation device accordingly.

According to one embodiment of the present invention, the control unit, after operating for T2 or more with the air volume of the ventilation device determined by the occupant deep sleep determination module, the current measured value of the indoor illuminance value is higher than the previous measured change When it is sensed, the occupant wake-up determination module for determining the air volume of the ventilation device as FN; may further include.

According to the control method and ventilation device of a ventilation device using an air monitor according to an embodiment of the present invention, the air quality is maintained comfortably by adjusting the air volume of the ventilation device in response to the presence of the user or the sleeping state of the user. At the same time, it is possible to improve the user's experience by improving the quality of the user's sleep.

1 is a flowchart illustrating a method for controlling a ventilation device using an air monitor according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a relationship between an air volume of a ventilation device according to a carbon dioxide concentration in a method for controlling a ventilation device using an air monitor according to an embodiment of the present invention.
3 is a flowchart illustrating a determination of the air volume of the ventilation device in the step of determining user access according to an embodiment of the present invention.
4 is a flowchart of determining the air volume of the ventilation device in the step of entering a bed of a occupant according to an embodiment of the present invention.
5 is a flowchart for determining the air volume of the ventilation device in the occupant's deep sleep phase according to an embodiment of the present invention.
6 is a flowchart illustrating an air flow rate of the ventilation device in the step of releasing an occupant from sleep and waking up the occupant according to an embodiment of the present invention.
7 is a block diagram of a ventilation device using an air monitor according to an embodiment of the present invention.

Hereinafter, the temporal precedence of each step is not limited to the listed order, and the temporal sequence of each step can be replaced, changed, or omitted to an extent apparent to those skilled in the art.

Hereinafter, the air monitor is interlocked with the ventilation device in the clean ventilation system and is a device that measures the air pollution level in the room. Indoor air quality information can be provided. In addition, the present invention may use other sensors capable of measuring the above-described indoor air quality information in addition to the air monitor.

1 is a flowchart of a method for controlling a ventilation device using an air monitor according to an embodiment of the present invention, and FIG. 2 is a method for controlling a ventilation device using an air monitor according to an embodiment of the present invention. The relationship between the air volume of the ventilation system according to the concentration is shown.

As shown in FIG. 1 , the method 100 for controlling a ventilation device using an air monitor according to an embodiment of the present invention is a control method for a ventilation device in which the air volume can be adjusted to F1 to FN, in which case F1<F2< .

As an embodiment, when N is 5, F1 is the lowest wind volume, F2 is a breeze, F3 is a weak wind, F4 is a strong wind, and F5 is a turbo wind as the maximum air volume. The air volume can be adjusted through a process such as controlling the power provided by the device.

As shown in FIG. 2 , the air volume of the ventilation device can be adjusted according to the concentration of carbon dioxide (CO2), and when the concentration of carbon dioxide is less than the first reference value, it is driven at F1, which is the lowest air volume, and the air quality increases as the concentration of carbon dioxide in the room increases. In case of contamination, the air volume of the ventilation system can be adjusted to F2, F3,..., FM in stages, and M is 2 or more and N-1 or less.

In addition, when the indoor carbon dioxide concentration exceeds the second reference value, the ventilation device air volume may be determined as the maximum air volume FN according to the stage determined by the user's indoor presence and occupant status, or the turbo wind cannot be used, but a lower air volume ( FM, in this case, 2≤M<FN) may determine the air volume of the ventilation device.

For example, when the occupant is in the deep sleep phase, the air volume of the ventilation device can be determined by FM so as not to disturb the occupant's deep sleep. With FN, the air volume of the ventilation system can be determined.

Accordingly, the air volume of the ventilation device may be determined according to the carbon dioxide concentration measured by the air monitor.

According to an embodiment of the present invention, the user access determination step (S110) of determining whether a user is in the room by detecting the indoor illuminance value and the carbon dioxide concentration measured by the air monitor, and determining the air volume of the ventilation device according to the presence of the user (S110) , When a user is present indoors in the user access determination step (S110) and a decrease in the indoor illuminance value is detected, the occupant's bedtime entry step (S120) of determining the air volume of the ventilation device as F1 during time T1 (S120), and In the occupant sleep entry step (S120), when a user is present in the room and the time T1 elapses after a change in the indoor illuminance value is sensed to decrease, the air volume of the ventilation device according to the carbon dioxide concentration measured by the air monitor It may include a occupant deep sleep step (S130) to determine the.

Specifically, in the user access determination step S110 according to an embodiment of the present invention, the current measured value of the indoor illuminance value is measured to be higher than the previous measured value by a predetermined value or more, and the current measured value of the carbon dioxide concentration is higher than the previous measured value In the measured occupancy state (a state in which a user exists in the room), ventilation may be performed according to the air volume of the ventilation device set by the user.

Alternatively, if the current measured value of the indoor illuminance value is less than or equal to the previous measured value, or the current measured value of the carbon dioxide concentration Depending on the air flow rate of the ventilation device may be determined.

In the user access determination step (S110), in the absence state, when the carbon dioxide concentration measured by the air monitor is less than the first reference value, the ventilation device is turned off, and the carbon dioxide concentration measured by the air monitor is the first reference value In an abnormal case, the ventilation device may be driven at an air volume FN. Since there is no user, the air quality can be quickly restored by determining the air volume of the ventilation device according to the measured air quality without considering the noise of the ventilation device.

In addition, the first reference value is a reference value set by the user, and as in the above embodiment, driving of the ventilation apparatus may be determined with only one reference value, or the driving and air volume of the ventilation apparatus may be determined in stages by setting a plurality of reference values. This is an exemplary embodiment and is not limited.

3 is a flowchart for determining the air volume of the ventilation device by the user access determination module 530 in the user access determination step (S110) according to an embodiment of the present invention, as shown in FIG. First, it is measured whether the indoor illuminance value measured by the air monitor or the illuminance sensor is highly changed (S1101). For example, it changes from the illuminance value when the indoor lighting is on to the illuminance value when the indoor lighting is off, or when the sunlight coming through the window is low (night) to high sunlight (morning). or when the average of the illuminance value when the indoor lighting is turned on and the illuminance value when it is turned off is set as the set value and the indoor illuminance value changes by more than the set value.

When the indoor illuminance value is highly changed (Yes in S1101), it is measured whether the carbon dioxide concentration has changed to a high value (S1102). For example, when a person enters a room and occupies the room, the indoor carbon dioxide concentration increases due to carbon dioxide emitted by the person.

When the carbon dioxide concentration changes to a high level (YES in S1102), the user is present in the room and the occupant is in the occupancy state, and the ventilation device may be operated according to the air volume set by the user. That is, the air volume of the ventilation device set by the user is maintained (S1103). However, when the user does not operate the ventilation device, the air volume of the ventilation device may be controlled according to the indoor carbon dioxide concentration.

On the other hand, as shown in FIG. 3 , when the indoor illuminance value is unchanged or changed to a low level (No in S1101), or when the indoor carbon dioxide concentration is unchanged or changed to a low level even when the indoor illuminance value is high (No in S1102), , determines the air volume of the ventilation system according to the indoor carbon dioxide concentration.

As shown in FIG. 3 , it is measured whether the carbon dioxide concentration is below the set value (S1104), and if the indoor carbon dioxide concentration is below the set value (YES in S1104), the operation of the ventilation device is stopped (S1105), and the indoor carbon dioxide concentration is set to the set value If it exceeds (NO in S1104), the air volume of the ventilation device is driven to the maximum air volume FN (S1106). Since there is no user in the room, it can be driven at the maximum air volume without being affected by noise. In this case, as shown in FIG. 2 , the set value of the indoor carbon dioxide concentration may be a first reference value or a second reference value, and a plurality of reference values may be set by further subdividing the reference value, and the setting may be changed to a concentration desired by the user. . The air volume of the ventilation device driven when the carbon dioxide concentration exceeds the set value may be determined by an air volume FM other than the maximum air volume FN (in this case, 1≤M<N).

In the user access determination step ( S110 ), the air volume or on/off of the ventilation device may be determined by periodically determining whether the user is present according to the indoor illuminance value and the indoor carbon dioxide concentration.

In addition, FIG. 4 is a flowchart for determining the air volume of the ventilation device by the occupant's sleep entry determining module 540 in the occupant's sleep entry step (S120) according to an embodiment of the present invention. As shown, the occupant's sleep entry step (S120) determines whether the user has entered the room to determine the user's occupancy (S1201), and if the user is occupant (YES in S1201), measure whether the indoor illuminance value has changed low (S1202) do. For example, it means that the user turns off a lighting device in a room after the user enters the room, turns off only some lighting devices in a plurality of lighting devices, or the time changes to night.

Therefore, if the indoor illuminance value changes to a low level (Yes in S1202), the user who entered the room, that is, the occupant, is regarded as a state just before entering the water surface, and the air volume of the ventilation device is determined as the lowest air volume, F1, and operation is performed. It can be (S1203). This is because the user is sensitive to noise just before entering the water surface, so the air volume of the ventilation device is determined with the lowest air volume so that noise does not occur, and the air volume is only ventilated to the extent that the temperature change is not felt, so that the user's entry to sleep is not disturbed.

Therefore, by measuring whether the indoor illuminance value has changed low (S1202), when the indoor illuminance value changes low and is maintained for a certain period of time, the user is considered to be sleeping and the ventilation apparatus is driven for a time set as the air volume F1 of the ventilation apparatus. That is, at this time, the ventilation device is driven by focusing on the noise of the ventilation device or the temperature change according to the ventilation rather than the carbon dioxide concentration.

On the other hand, if the user does not enter the room in the user occupancy determination (S1201) or the user leaves the room and is not occupied (No in S1201), it returns to the user occupancy status (S1201), and the occupant sleep entry determination module 540 ) determines whether the user is occupant (S1201) and checks whether there is a occupant who is scheduled to enter the bed.

At this time, if the user is not present (No in S1201), the air volume of the ventilation device is determined by the user access determination module 530, and as shown in FIG. 3, it is measured whether the carbon dioxide concentration is below the set value (S1104) ) and when the indoor carbon dioxide concentration is below the set value (Yes in S1104), stop the operation of the ventilation system (S1105), and when the indoor carbon dioxide concentration exceeds the set value (No in S1104), the air quality is poor. It is possible to drive the air volume to the maximum air volume FN (S1106). Contents overlapping with the above are omitted for the sake of simplicity and clarity of description.

In addition, by measuring whether the indoor illuminance value has changed low (S1202), if the indoor illuminance value is unchanged or changed to a high value (NO in S1202), it is possible to go back and determine the occupancy of the user (S1201).

In addition, in the occupant deep sleep step (S130) according to an embodiment of the present invention, the air volume of the ventilation device may be determined in proportion to the carbon dioxide concentration measured by the air monitor, and the air volume of the ventilation device is set to F1 to FM. can decide In this case, M is 2≤M<N.

Specifically, according to an embodiment of the present invention, the occupant deep sleep step ( S130 ) may be determined as F1 to FN-1 excluding FN, which is the maximum air volume. When the carbon dioxide concentration is the first step, the air volume of the ventilation device is determined as F1, and when the carbon dioxide concentration is the second step, the air volume of the ventilation device is determined as F2, and the carbon dioxide concentration is N-1 If the stage or more, the air volume of the ventilation device may be determined as FN-1. The ventilation system is not operated at the maximum air volume so as not to affect the occupant's sound sleep, and the ventilation system is controlled based on the concentration of carbon dioxide, which is an important factor for a sound sleep, to improve the user's experience and improve the air quality quickly.

That is, as the carbon dioxide concentration increases and the air quality deteriorates, the carbon dioxide concentration step increases, and it can be determined by the air volume of the ventilation device set to correspond to the carbon dioxide concentration step, but in the occupant deep sleep step (S130), F1 to FM (2≤M<N) will be driven by

5 is a flowchart of determining the air volume of the ventilation device by the occupant deep sleep determination module 550 in the occupant deep sleep step (S130) according to an embodiment of the present invention. As shown in FIG. 5, the occupant In the deep sleep step (S130), it is determined whether the user has entered the room and the user occupancy is determined (S1301). For example, it means that the user turns off the lighting device in the room after the user enters the room, or the time changes to night.

Therefore, by counting the time after the change of the indoor illuminance value (S1303), the indoor illuminance value changes low (Yes in S1302), after the indoor illuminance value changes low and before time T1 elapses (No in S1303), the user is considered to be in a light sleep state, and determines and operates the air volume of the ventilation device as the lowest air volume F1 to minimize noise (S1304). (Yes in S1303), it is determined that the user is sleeping well, and the air volume of the ventilation device is determined in proportion to the indoor carbon dioxide concentration.

When users enter deep sleep, they become less sensitive to noise and temperature changes, and it is important to keep the carbon dioxide concentration low in order to improve the quality of sleep. Therefore, in order to prevent disturbing the user's deep sleep with excessive noise, the air volume of the ventilation device can be determined at the air volume F1 to FM (2≤M<N) according to the carbon dioxide concentration, except for the turbo wind FN, which is the maximum air volume. .

As a specific example, as shown in FIG. 5 , when the indoor carbon dioxide concentration is less than the first reference value (Yes in S1305), the indoor carbon dioxide concentration is low and the air quality is set to F1, which is the minimum air volume in the 'good stage'. It is possible to determine and operate the air volume of the ventilation device (S1306).

In addition, when the indoor carbon dioxide concentration is greater than or equal to the first reference value and less than the second reference value (NO in S1305 & NO in S1307), the air volume of the ventilation device may be determined as FN-2 and may be operated (S1309). In addition, when the indoor carbon dioxide concentration is equal to or greater than the second reference value (YES in S1307), the air volume of the ventilation device may be determined and operated as FN-1 (S1308).

For example, when N is 4, the indoor carbon dioxide concentration is greater than the first reference value and less than the second reference value (S1305-No & S1307-No), the air volume of the ventilation device is F2, and the indoor carbon dioxide concentration is the second If it is higher than the standard value (S1307-Yes), the airflow rate of the ventilation device is set to F3, and when the user is in a deep sleep state, it does not operate at the maximum air volume F4. Through this, while actively managing the carbon dioxide concentration, it is possible to reduce noise as much as possible to manage the user's deep sleep while sleeping and to improve the quality of his sleep.

On the other hand, according to an embodiment of the present invention, the current measured value of the indoor illuminance value is measured to be higher than the previous measured value while the air volume of the ventilation device is operating at F1 (NO in S1403) in the occupant's sleep entry step (S120) A change is detected (YES in S1405), or a change in which the current measured value of the indoor illuminance value is higher than the previous measured value within T2 time (NO in S1404) from entering the occupant deep sleep step (S130) ( If yes) in S1405, the occupant sleep release step (S140) may further include returning to the user access determination step (S110) of determining whether the user is occupant.

In addition, according to an embodiment of the present invention, after more than T2 time has elapsed (YES in S1404) from the time the occupant enters the deep sleep step (S130), the current measured value of the indoor illuminance value is higher than the previous measured change. If it is detected (YES in S1406), it may further include a occupant wake-up step (S140a) of determining the air volume of the ventilation device as the maximum air volume FN.

6 is a diagram showing the air volume of the ventilation device by the occupant's sleep release determination module 560 or the occupant's wakeup determination module 570 in the occupant's sleep release step (S140) and the occupant's wake-up step (S140a) according to an embodiment of the present invention. A flowchart for determining

As shown in FIG. 6 , when the user is in the room (Yes in S1401), that is, when the user is occupant, 'changing the indoor illuminance value to high' (No in S1402) indicates that the user does not intend to sleep. , and may return to S1401 to determine another user entry. That is, it returns to the user access determination step (S110).

Specifically, as shown in FIG. 6 , the user occupancy is determined by determining whether the user has entered the room (S1401), and when the user is occupant (YES in S1401), whether the indoor illuminance value has changed low is measured (S1402) do.

Therefore, after the indoor illuminance value changes to a low level (Yes in S1402), before time T1 elapses (No in S1403), if the indoor illuminance value changes to a high value (Yes in S1405), it is considered that the user has no intention of deep sleep and may return to S1401 to determine another user's entry.

For example, if the indoor illuminance value changes to a low level (Yes in S1402) and the ventilation device is driven at the lowest air volume F1 during the T1 time, judging by the occupant sleep entry step (S120), the indoor If the lighting device is turned on (No in S1403 & Yes in S1405), it returns to S1401 again to determine whether a new user enters. On the other hand, if the indoor lighting device is not turned on even before T1 elapses (NO in S1403) and the indoor illuminance value is unchanged or changed to a lower value (NO in S1405), the process returns to S1403 (S1407).

After the change in the indoor illuminance value, the time T1 + T2 is measured (S1404), which drives the ventilation device at the air volume of F1 during the time T1 during the occupant sleep entry step (S120), and the time T1 elapses (Yes in S1403), and the occupant After entering the deep sleep step (S130), it is determined whether time T2 has elapsed (S1404). After entering the occupant deep sleep step (S130), before the T2 time elapses (No in S1404), the occupant has not yet entered a deep sleep, and at this time, 'In case the indoor illuminance value changes to high (Yes in S1405), a new user It goes back to S1401 again to determine whether or not. On the other hand, if the indoor lighting device is not turned on before T2 elapses (NO in S1404) and the indoor illuminance value is unchanged or changed to a lower value (NO in S1405), the process returns to S1404 (S1407).

Meanwhile, in the occupant wake-up step (S140a) according to an embodiment of the present invention, as shown in FIG. 6 , after the indoor illuminance value changes to a low level, the T1+T2 transition is measured (S1404), and the occupant deep sleep step (S1404) S130) If time T2 has elapsed after entering (Yes in S1404), the occupant enters a deep sleep, and at this time, if the 'indoor illuminance value changes to a high level (Yes in S1406), it can be considered that the occupant has woken up after a deep sleep have.

In this case, assuming that the occupant is engaged in activities such as dusting a blanket or making a bed or leaving the room, the air volume of the ventilation device can be determined with the maximum air volume FN to remove dust due to movement (S1408) . In this case, the maximum air volume can be driven regardless of noise so that the occupant's wake-up alarm function can be performed. On the other hand, when the indoor illuminance value does not change high or changes low (NO in S1406), it is possible to assume a occupant deep sleep state and return to S404 to detect a wake-up phase in which the occupant is awakened (S1409). In addition, the occupant deep sleep determination module 550 may determine the air volume of the ventilation device in proportion to the carbon dioxide concentration.

Alternatively, if a change in the current measured value of the indoor illuminance value measured lower than the previous measured value is detected in the occupant's sleep entry step (S120) or the occupant deep sleep step (S130), return to each step and detect the measured value Instead of changing the air volume of the ventilation system, you can keep it as it is.

On the other hand, when the user does not enter the room in the user occupancy determination (S1401) or the user leaves the room and is not present (No in S1401), the air volume of the ventilation device according to the indoor carbon dioxide concentration by the user access determination module 530 can be decided The above-described and omitted details will be omitted for the sake of brevity of the specification.

That is, if the lighting device is turned on when the occupant is in the bedtime step (S120) or a sufficient time (for example, T2) has not elapsed in the occupant deep sleep step (S130), the occupant sleep release step (S140) can be viewed. . In addition, when the lighting device is turned on after a sufficient time T2 has elapsed in the deep sleep step S130 by the occupant, the control of the air volume of the ventilation device may be differently performed in the wake-up step S140a of the occupant.

As another aspect of the present invention, as shown in FIG. 7 , in the ventilation device 500 using the air monitor 510 according to an embodiment of the present invention, the air volume can be adjusted to F1 to FN, in which case F1 < F2<...<FN, N is 3 or more, FN is a maximum air volume that the ventilation device 500 can drive, F1 is a preset minimum air volume, and a ventilation device configured to proportionally increase as the number increases As 500, the air monitor 510 for measuring indoor air quality information including the indoor illuminance value and carbon dioxide concentration in real time, and the ventilation device 500 according to the indoor air quality information measured by the air monitor 510 ) may include a control unit for determining the air volume.

The control unit, a user access determination module 530, which determines whether a user is in the room according to the carbon dioxide concentration and the indoor illuminance value measured by the air monitor 510, and determines the air volume of the ventilation device according to the presence of the user; When it is determined by the user access determination module 530 that a user exists in the room, and when a decrease in the indoor illuminance value is detected, the occupant sleep access determination module 540 determines the air volume of the ventilation device as F1 for a time T1. ) and when it is determined by the user access determination module 530 that a user is present in the room, when the T1 time elapses after a change in the indoor illuminance value is sensed to decrease, the carbon dioxide concentration measured by the air monitor is Accordingly, it may include a occupant deep sleep determination module 550 that determines the air volume of the ventilation device.

In this case, according to another embodiment of the present invention, an illuminance sensor 520 for measuring the indoor illuminance value may be included. The illuminance sensor 520 is a sensor including an LED and a dot matrix and may additionally determine illuminance, or may detect illuminance using the air monitor 510 and omit the illuminance sensor 520 . That is, although both the air monitor 510 and the illuminance sensor 520 are illustrated in FIG. 7 , the illuminance sensor 520 may be omitted.

According to an embodiment of the present invention, the control unit, the current measured value of the indoor illuminance value is higher than the previous measured value while operating at the air volume F1 of the ventilation device 500 determined by the occupant sleep entry determination module 540 . When detecting a change in which the current measured value of the indoor illuminance value is higher than the previous measured value within T2 time during operation with the measured change or the air volume of the ventilation device 500 determined by the occupant deep sleep determination module 550, the The user access determination module 530 may further include a occupant sleep release determination module 560 that drives the ventilator 500 to determine the air volume according to the presence or absence of the next user.

According to an embodiment of the present invention, the control unit operates at the air volume of the ventilation device 500 determined by the occupant deep sleep determination module 550 for more than T2 time, and then the current measured value of the indoor illuminance value is the previous measured value. The occupant wakeup determination module 570 may further include a occupant wakeup determination module 570 that determines the air volume of the ventilation device 500 as FN when a higher measured change is detected. The content overlapping with the above will be omitted for the sake of brevity of the specification.

In the above, the present invention has been described mainly with respect to the embodiments, but the present invention is not limited to the above-described embodiments, and can be modified and practiced by those skilled in the art without changing the technical spirit of the present invention as claimed in the claims. Of course.

500: ventilation device
510: air monitor 520: light sensor
530: user access determination module 540: occupant sleep access determination module
550: occupant deep sleep determination module 560: occupant sleep release determination module
570: occupant wake-up judgment module

Claims (10)

As a control method of a ventilation device that can adjust the air volume to F1 to FN,
A user access determination step of determining whether a user is in the room by detecting the indoor illuminance value and the carbon dioxide concentration measured by the air monitor, and determining the air volume of the ventilation device according to the presence of the user;
a occupant's bedtime entry step of determining the air volume of the ventilation device to be F1 for a time T1 when a user is present in the room and a change in the indoor illuminance value is detected in the user access determination step; and
a occupant deep sleep step of determining the air volume of the ventilation device according to the carbon dioxide concentration measured by the air monitor when the time T1 elapses after a change in the indoor illuminance value is detected in the occupant sleep entry step; includes,
At this time, F1<F2<...<FN, N is 3 or more, FN is the maximum air volume that the ventilation device can drive, F1 is the preset minimum air volume, and as the number increases, the air volume proportionally increases. Control method of ventilation device using
According to claim 1,
In the step of entering the occupant's sleep, a change in which the current measured value of the indoor illuminance value is higher than the previous measured value is detected while the air volume of the ventilation device is operating at F1;
When a change is detected in which the current measured value of the indoor illuminance value is higher than the previous measured value within T2 time from entering the occupant deep sleep stage, the occupant sleep release step of returning to the user access determination step; Control method of ventilation device using.
According to claim 1,
After T2 time or more has elapsed since entering the occupant deep sleep phase, when a change in which the current measured value of the indoor illuminance value is higher than the previous measured value is detected, the occupant wake-up step of determining the air volume of the ventilation device as FN Further comprising, a method of controlling a ventilation device using an air monitor.
According to claim 1,
The user access determination step is,
In the occupancy state in which the current measured value of the indoor illuminance value is measured to be higher than the previous measured value by a predetermined value or more, and the current measured value of the carbon dioxide concentration is measured to be higher than the previous measured value, ventilation is performed according to the air volume of the ventilation device set by the user,
In an absence state in which the current measured value of the indoor illuminance value is less than or equal to the previous measured value, or the current measured value of the carbon dioxide concentration is measured to be less than or equal to the previous measured value, determining the air volume of the ventilation device according to the current measured value of the carbon dioxide concentration,
Control method of ventilation device using air monitor.
5. The method of claim 4,
The user access determination step, in the absence state,
When the carbon dioxide concentration measured by the air monitor is less than the first reference value, the ventilation device is turned off,
When the carbon dioxide concentration measured by the air monitor is equal to or greater than a first reference value, the ventilation apparatus is driven at an air volume FN.
According to claim 1,
The occupant's deep sleep phase is
A method of controlling a ventilation device using an air monitor, wherein the air volume of the ventilation device is determined in proportion to the carbon dioxide concentration measured by the air monitor.
7. The method of claim 6,
The air volume of the ventilation device is determined by F1 to FM, wherein M is 2≤M<N.
The air volume can be adjusted from F1 to FN, where F1<F2<...<FN, N is 3 or more, FN is the maximum air volume that the ventilation device can drive, F1 is the preset minimum air volume, and the number increases As a ventilation device configured to increase the air volume in proportion,
an air monitor that measures indoor air quality information including indoor illuminance value and carbon dioxide concentration in real time; and
Includes; a control unit that determines the air volume of the ventilation device according to the indoor air quality information measured by the air monitor;
The control unit is
a user access determination module for determining whether a user is in the room according to the carbon dioxide concentration and the indoor illuminance value measured by the air monitor, and determining an air volume of the ventilation device according to the presence of the user;
an occupant bedtime entry determination module that determines, when it is determined by the user access determination module that a user exists in the room, that a decrease in the indoor illuminance value is detected, determines the air volume of the ventilation device as F1 for a time T1; and
When it is determined by the user access determination module that a user exists in the room, when the T1 time elapses after a change in the indoor illuminance value is sensed to decrease, according to the carbon dioxide concentration measured by the air monitor, occupant deep sleep determination module to determine the air volume;
A ventilation device using an air monitor comprising a.
The method of claim 8, wherein the control unit,
a change in which the current measured value of the indoor illuminance value is higher than the previous measured value while operating at the air volume F1 of the ventilation device determined by the occupant's bedtime determination module; or
Upon detecting a change in which the current measured value of the indoor illuminance value is higher than the previous measured value within T2 time during operation with the air volume of the ventilation device determined by the occupant deep sleep determination module, the user access determination module determines whether the next user is present or not Ventilation device using an air monitor further comprising;
The method of claim 8, wherein the control unit,
After operating for more than T2 time with the air volume of the ventilation device determined by the occupant deep sleep determination module, when a change in which the current measured value of the indoor illuminance value is measured to be higher than the previous measured value is detected, the air volume of the ventilation device is determined as FN Ventilation device using an air monitor further comprising a; occupant wake-up determination module.

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