KR20100078209A - Sleep operating control method of a heat recovery ventilator - Google Patents

Abstract

PURPOSE: A method of controlling a heat recovery ventilator for sleeping hours is provided to perform ventilating operation under an optimal condition and to minimize the noise of a heat recovery ventilator based on the currently sensed pollution level of indoor air, indoor light intensity, and the sleeping pattern of a human body in the state a user selected a sleeping mode. CONSTITUTION: A method of controlling a heat recovery ventilator for sleeping hours is as follows. If a user turns on the heat recovery ventilator by operating a remote controller(S10'), the remote controller determines whether the user selected the sleeping mode(S11'). If yes, the remote controller determines whether the pollution level of current indoor air sensed by a pollution sensor is over a predetermined pollution determination value(S12'). If the pollution level is below the predetermined pollution determination value, the operation of the air exhaust fan and the air supply fan of the heat recovery ventilator stops. If the pollution level is over the predetermined pollution determination value, the remote controller determines whether the current indoor light intensity sensed by a light intensity sensor is below a predetermined sleeping determination value. If yes, after a predetermined sleeping standby time(S15') passes, the remote controller controls the opening/closing of an air exhaust damper and an air supply damper simultaneously with controlling the output of the air exhaust fan and the air supply fan of the heat recovery ventilator to a predetermined specific value depending on the sleeping patterns of a human body repeating four sleeping patterns for a user-defined time.

Description

Sleep operating control method of a heat recovery ventilator

The present invention relates to a ventilation device control technology, and more particularly, to a method for controlling the sleep operation of a waste heat recovery type ventilation device for controlling the output of the exhaust fan and the supply fan and the opening and closing of the exhaust damper and the supply damper according to the sleep pattern of the human body. will be.

In general, enclosed indoor air is contaminated with carbon dioxide (CO ₂ ) or Total Volatile Organic Compounds (TVOC), which increases with time due to dust or breathing of humans or animals. It is disturbed.

Therefore, it is necessary to replace the contaminated indoor air from time to time by providing outdoor fresh air indoors in private houses, common houses, offices, etc., which is used for the ventilation device.

Among the ventilation devices described above, the waste heat recovery type ventilation device 100 as shown in FIG. 1 operates the exhaust fan 110 during the operation of the air conditioner through the indoor exhaust damper 111 and the outdoor exhaust damper 112. When the indoor air is discharged to the outside, the waste heat of the indoor air cooled by the heat exchanger 120 is recovered, and the air supply fan 130 is operated to operate the outdoor air supply damper 131 and the indoor air supply damper 132. An energy-saving ventilator that prevents heat loss of air-cooled indoor air by adding waste heat of indoor air recovered by the heat exchanger 120 to outdoor fresh air when supplying fresh air to the room. It is known that 20-30% can be saved.

The exhaust filter 121 installed at the indoor exhaust damper 111 side of the waste heat recovery type ventilation device 100 filters the indoor air discharged to the outside through the heat exchanger 120 and is installed at the heat exchanger 120. The outdoor air supplied to the room is filtered through the air supply filter 122.

The waste heat recovery type ventilation apparatus 100 adds the collected cold to the outdoor hot fresh air while the cooled indoor air is discharged to the outside, and the recovered cold air is supplied to the outdoor hot fresh air. Lower the temperature of the supplied air, or recover the warmth when the heated indoor air is discharged to the outside, and add the recovered warmer to the indoor cool fresh air when the cold fresh air is supplied. By raising the temperature of the air to be supplied, the indoor cooling and heating efficiency is prevented from being lowered.

The waste heat recovery type ventilation device 100 is operated and controlled by a user operating a room remote control unit 200 for controlling a ventilation device in a room, and the exhaust fan 110 has a specific value selected by a user, usually divided into strong, medium, or weak. ) And the exhaust fan 110 and the air supply fan to a specific value preset in order to ventilate the indoor air at an optimal condition according to the pollution degree of the indoor air while minimizing noise and controlling the output of the air supply fan 130. Operation control is performed in an automatic mode that controls the output of 130.

FIG. 2 is a flowchart illustrating a method for controlling the operation of a conventional waste heat recovery type ventilator 100, and is installed in a room remote control unit 200 for controlling the indoor air pollutant to determine the degree of pollution of indoor air. (CO ₂ ) utilizes a pollution detection sensor 210 to detect the concentration.

Referring to FIG. 2, when a user first operates a room remote controller 200 to turn on the waste heat recovery type ventilation device 100 (S10), the room remote controller 200 may be operated by a user. In order to control the output of the exhaust fan 110 and the air supply fan 130 to a specific value selected by selecting a normal mode, or to minimize the noise while ventilating the indoor air in the optimal conditions according to the pollution degree of the indoor air In step S11, it is determined whether the automatic mode is selected.

In this case, if the general mode is selected, the room remote controller 200 controls the output of the exhaust fan 110 and the air supply fan 130 to a specific value selected by the user as divided into strong, medium, or weak (S12). Return to step S10.

On the other hand, when the automatic mode is selected, the room remote controller 200 determines whether the pollution degree of the current indoor air detected by the pollution degree sensor 210 is greater than or equal to a predetermined pollution determination value (S13).

If the pollution degree of the current indoor air is greater than or equal to the pollution determination value, the room remote controller 200 controls the output of the exhaust fan 110 and the air supply fan 130 to a predetermined value (S14), and in step S10. Return to. Accordingly, it is possible to ventilate the contaminated indoor air to an optimal condition while minimizing the noise of the waste heat recovery type ventilation device 100.

On the other hand, if the pollution degree of the current indoor air is less than the pollution determination value, since the current pollution degree of the indoor air is not enough to require ventilation, the room remote control 200 is the exhaust fan 110 Without operating the supercharge fan 130 (S15), and returns to the step S11.

On the other hand, the conventional waste heat recovery type ventilation device 100 as described above, when the user controls the operation in the automatic mode for bedtime, the user determines the pollution degree of the indoor air during normal daily life in the room during the day in advance Since the output of the exhaust fan 110 and the air supply fan 130 is controlled to a predetermined value based only on the pollution determination value of the indoor air to be set, the room is minimized while minimizing noise in response to a user's sleeping pattern that changes frequently at bedtime. According to the pollution of the air there is a disadvantage that can not ventilate the indoor air in the optimum conditions.

SUMMARY OF THE INVENTION The present invention is directed to solving the conventional problems as described above, and an object of the present invention is to provide shallow sleep (eg, 20 minutes), heavy sleep (eg, 20 minutes), deep during user set time (eg, 90 minutes). Ventilate indoor air to optimal conditions while minimizing noise based on human sleep patterns that repeat four different sleep patterns: sleep (eg, 30 minutes) and REM (Rapid Eye Movement) (eg, 20 minutes) Surface operation control method of the waste heat recovery type ventilator that controls the operation of the waste heat recovery type ventilator in the sleep mode that controls the output of the exhaust fan and the supply fan and the opening and closing of the exhaust damper and the supply damper to a predetermined value. To provide.

In order to achieve the object of the present invention as described above, the sleep operation control method of the waste heat recovery type ventilation apparatus according to the present invention, when the user operates the room remote control to turn on the power of the waste heat recovery type ventilation apparatus, Determining whether a user has selected a sleep mode in order to ventilate indoor air to an optimal condition while minimizing noise according to a human sleeping pattern; As a result of determining whether the sleep mode is selected, if the sleep mode is selected, determining, by the remote control room, whether the pollution degree of the current indoor air detected by the pollution degree sensor is greater than or equal to a predetermined pollution determination value; A third step of stopping the operation of the exhaust fan and the air supply fan and returning to the second step if the pollution degree of the current indoor air is less than the pollution determination value in the second step; As a result of determining the pollution degree in the second process, if the pollution degree of the current indoor air is equal to or greater than the pollution determination value, the room remote controller determines whether or not the illuminance of the current room detected by the illuminance sensor is equal to or less than the predetermined sleep determination value, and the determination result. A fourth process of returning to a first process if the illuminance of the current room is greater than the sleep determination value; And if the illuminance determination result of the fourth step is that the current room illuminance is less than the sleep determination value, after the sleep waiting time set in advance by the room remote controller has elapsed, during the user setting time, the sleep, mid sleep, deep sleep, REM sleep and A fifth step of controlling opening and closing of the exhaust damper and the air supply damper while controlling the outputs of the exhaust fan and the air supply fan of the waste heat recovery type ventilation apparatus according to the sleep patterns of repeating the four sleep patterns as described above; Characterized in that made.

According to the present invention, according to the present invention, the polluted indoor air is optimally ventilated while minimizing the noise of the waste heat recovery type ventilator according to the pollution of indoor air and the illuminance of the room and the sleep pattern of the human body. It can minimize the heat loss of indoor air.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 3, the waste heat recovery type ventilation device 100 according to the present invention operates the exhaust fan 110 during the operation of the air conditioner to provide indoor air through the indoor exhaust damper 111 and the outdoor exhaust damper 112. When discharging to the outdoor, the waste heat of the indoor air cooled by the heat exchanger 120 is recovered, and the air supply fan 130 is operated so that the fresh air of the outdoor is indoors through the outdoor air supply damper 131 and the indoor air supply damper 132. An energy-saving ventilator that prevents heat loss of air-conditioned indoor air by adding waste heat of indoor air recovered by the heat exchanger 120 to outdoor fresh air when supplying air to the air. It is known to save%.

The exhaust filter 121 installed at the indoor exhaust damper 111 side of the waste heat recovery type ventilation device 100 filters the indoor air discharged to the outside through the heat exchanger 120 and is installed at the heat exchanger 120. The outdoor air supplied to the room is filtered through the air supply filter 122.

The waste heat recovery type ventilation apparatus 100 adds the collected cold to the outdoor hot fresh air while the cooled indoor air is discharged to the outside, and the recovered cold air is supplied to the outdoor hot fresh air. Lower the temperature of the supplied air, or recover the warmth when the heated indoor air is discharged to the outside, and add the recovered warmer to the indoor cool fresh air when the cold fresh air is supplied. By raising the temperature of the air to be supplied, the indoor cooling and heating efficiency is prevented from being lowered.

The waste heat recovery type ventilation device 100 is operated and controlled by a user operating a room remote control unit 200 for controlling a ventilation device in a room, and the exhaust fan 110 has a specific value selected by a user, usually divided into strong, medium, or weak. ) And the sleep mode (eg, 20 minutes), heavy water (eg, 20 minutes), deep sleep (eg, 30 minutes) during normal mode and user set time (eg, 90 minutes) to control the output of the air supply fan 130. ), The output of the exhaust fan 110 and the air supply fan 130 of the waste heat recovery type ventilation apparatus 100 according to the human sleep pattern which repeats four sleep patterns such as REM sleep (for example, 20 minutes) Operation is controlled in a sleep mode that controls the opening and closing of the exhaust dampers 111 and 112 and the air supply dampers 131 and 132 while controlling to a value. Herein, the user setting time may be arbitrarily set by the user for the sleep mode driving control, and the user may arbitrarily set the shallow sleep time, the deep sleep time, the deep sleep time, and the REM sleep time in consideration of his / her human sleeping pattern. Can be.

The sleep mode of the waste heat recovery type ventilation device 100 is an operation control mode selected when the user needs the sleep operation control as shown in FIG. 4 to sleep, and the exhaust fan 110 and the air supply in the sleep mode. The output of the fan 130 is a specific value for minimizing the noise of the waste heat recovery type ventilator 100 that the user feels while sleeping, while ventilating the contaminated indoor air to an optimal condition and minimizing heat loss of the indoor air. It is set in advance.

4 is a flowchart illustrating a method for controlling late night operation of the waste heat recovery type ventilation device 100 according to the present invention, which is a means for determining the start of the late night operation in a state where the sleep mode is selected, as shown in FIG. 3. In order to determine the pollution degree of the indoor air conditioner control room remote control unit 200 is installed in the pollution control sensor 210 for detecting the TVOC concentration or carbon dioxide (CO ₂ ) concentration of the indoor air, and the room remote control room control ( It is installed on the 200 to utilize the illumination sensor 220 for detecting the indoor illumination. In addition, in order to minimize the heat loss of the indoor air utilizes the indoor and outdoor temperature sensor 230 for detecting the temperature of the indoor and outdoor air.

Referring to FIG. 4, when a user first operates a room remote controller 200 to turn on the waste heat recovery type ventilation device 100 (S10 ′), the room remote controller 200 may be connected to a human sleeping pattern. Accordingly, it is determined whether the sleep mode is selected in order to minimize indoor noise while minimizing noise and to minimize heat loss of indoor air (S11 ').

As a result of determining whether the sleep mode is selected, if the sleep mode is selected, the room remote controller 200 determines whether the pollution degree of the current indoor air detected by the pollution degree sensor 210 is greater than or equal to a predetermined pollution determination value. (S12 ')

At this time, if it is determined that the pollution degree of the current indoor air is smaller than the pollution determination value, the room remote controller 200 stops the operation of the exhaust fan 11 and the air supply fan 130 and returns to the process S12 '(S13'). ).

On the other hand, if the pollution degree of the current indoor air is determined to be above the pollution determination value, the room remote controller 200 determines whether the current indoor illumination intensity detected by the illuminance sensor 220 is less than or equal to the predetermined sleep determination value. If it is determined (S14 '), if the illuminance of the current room is greater than the sleep determination value, it is determined that the indoor lighting device is turned on, and the process returns to the step S11' of determining whether the sleep mode is selected.

As a result of the above-described indoor illuminance determination, if the illuminance of the current room is less than the above-described sleep determination value, the room remote controller 200 first determines whether a predetermined sleep waiting time (for example, the first 10 minutes) has elapsed (S15). ').

In this case, if it is determined that the sleep waiting time has not elapsed, the room remote controller 200 returns to step S11 'to determine whether to select a sleep mode.

On the other hand, at this time, if it is determined that the sleep waiting time has elapsed, the room remote controller 200 has passed since the sleep waiting time has elapsed, for example, a shallow sleep 20 minutes, a heavy sleep 20 minutes, The exhaust dampers 111 and 112 and the air supply are controlled while controlling the output of the exhaust fan 110 and the air supply fan 130 to a predetermined value according to the human sleep pattern which repeats four sleep patterns such as 30 minutes of deep sleep and 20 minutes of REM sleep. The process returns to step S11 'to control the opening and closing of the dampers 131 and 132 and to determine whether the sleep mode is selected (S16'). That is, it is determined that the first 10 minutes after the indoor lighting device is turned off before the user falls asleep, and after the sleep waiting time has elapsed, the user determines that the user has actually fallen asleep and starts the sleep mode control.

In this case, more specifically, the waste heat recovery is set to a predetermined value so as to minimize the noise of the waste heat recovery type ventilator according to the sleep patterns of the human body and to ventilate the contaminated indoor air to an optimal condition and to minimize the heat loss of the indoor air. While controlling the output of the exhaust fan 110 and the air supply fan 130 of the type ventilator 100 to control the opening and closing of the exhaust damper (111, 112) and the air supply damper (131, 132). Accordingly, while minimizing the noise of the waste heat recovery type ventilation device 100 that the user feels while sleeping, the contaminated indoor air can be ventilated to an optimal condition and the heat loss of the indoor air can be minimized.

According to the human body sleep pattern, the room remote controller 200 repeats four sleep patterns such as shallow sleep 20 minutes, medium sleep 20 minutes, deep sleep 30 minutes, and REM sleep 20 minutes for 90 minutes after the sleep waiting time has elapsed. Returning to the process S11 'which controls the opening and closing of the exhaust dampers 111 and 112 and the air supply dampers 131 and 132 while controlling the output of the exhaust fan 110 and the air supply fan 130 to a predetermined value, and determines whether to select a sleep mode. The (S16 ') process is described in more detail as follows.

When the sleep waiting time elapses as described above (S15 ′), the room remote controller 200 firstly opens the exhaust dampers 111 and 112 of the waste heat recovery type ventilator 100 for the first 20 minutes of shallow sleep and opens the air supply dampers 131 and 132. Ventilation is performed while increasing the output of the exhaust fan 110 from the minimum (MIN) 10% to the maximum (MAX) 40% in the closed state. In this shallow sleep phase, the person wakes up even with a slight movement or a small sound, so the air supply fan 130 stops operating. In addition, when the indoor and outdoor temperature difference detected by the indoor and outdoor temperature sensor 230 during the ventilation is 4 ℃ or more, that is, when the indoor air cooling the outdoor temperature is 4 ℃ or more higher than the room temperature, or when the indoor air heating the indoor temperature is outdoor If the temperature is higher than 4 ° C., the operation of the exhaust fan 110 is stopped in order to minimize the heat loss of the indoor air caused by exhausting the indoor air to the outside.

After performing the operation control of the waste heat recovery type ventilator 100 for the first 20 minutes of the shallow water surface, the room remote controller 200 secondly performs an exhaust damper (20) of the waste heat recovery type ventilator 100 for the middle water surface 20 minutes. With the 111 and 112 and air supply dampers 131 and 132 open, the output of the exhaust fan 110 is increased from the minimum (MIN) 40% to the maximum (MAX) 60% and the output of the air supply fan 130 is minimum (MIN) 10 Ventilation is performed from% to maximum 40%. In this heavy water phase, the muscles of the human body are relaxed to some extent and the human body goes to the deep sleep phase, thereby operating the exhaust fan 110 and the air supply fan 130 to perform optimal ventilation. In addition, when the indoor and outdoor temperature difference detected by the indoor and outdoor temperature sensor 230 during the ventilation is 10 ℃ or more, that is, the outdoor temperature when the indoor air cooling is more than 10 ℃ higher than the room temperature, or the indoor temperature when the indoor air heating If the temperature is higher than 10 ° C, in order to minimize the heat loss of the indoor air while the outdoor air is supplied to the indoor air, the air supply fan 130 is stopped and the air supply dampers 131 and 132 are closed to prevent the outdoor air from being supplied into the air. do.

As described above, after performing the operation control of the waste heat recovery type ventilation device 100 for 20 minutes in the middle of the water surface, the room remote controller 200 performs an exhaust damper (3) of the waste heat recovery type ventilation device 100 for the third deep water surface. With the 111 and 112 and air supply dampers 131 and 132 open, the output of the exhaust fan 110 is increased from the minimum (MIN) 60% to the maximum (MAX) 90% and the output of the air supply fan 130 is minimum (MIN) 40 Ventilation is performed from% to MAX 90%. In this heavy sleep phase, the human body is completely asleep, the muscles are completely relaxed, and the brain also enters a completely rest mode, thereby operating the exhaust fan 110 and the air supply fan 130 to perform optimal ventilation.

After performing the operation control of the waste heat recovery type ventilation device 100 for the third deep sleep 30 minutes as described above, the room remote controller 200 fourthly exhausts the damper of the waste heat recovery type ventilation device 100 for 20 minutes of REM sleep. With the openings 111 and 112 and the air supply dampers 131 and 132 open, the outputs of the exhaust fan 110 and the air supply fan 130 are reduced from maximum 90% to minimum 10%, respectively, to perform ventilation. In this REM sleep stage, the brain of the human body is mainly awake while dreaming, so the air supply fan 130 stops the operation in order to minimize external stimulation. In addition, when the indoor and outdoor temperature difference detected by the indoor and outdoor temperature sensor 230 during the ventilation is 10 ℃ or more, that is, the outdoor temperature when the indoor air cooling is more than 10 ℃ higher than the room temperature, or the indoor temperature when the indoor air heating If the temperature is higher than 10 ° C, in order to minimize the heat loss of the indoor air while the outdoor air is supplied to the indoor air, the air supply fan 130 is stopped and the air supply dampers 131 and 132 are closed to prevent the outdoor air from being supplied into the air. do.

The sleep operation control method of the waste heat recovery type ventilation apparatus according to the present invention described above is not limited to the above-described embodiment, and is usually used in the field of the present invention without departing from the gist of the present invention as claimed in the following claims. Anyone who has the knowledge of R & D has the technical spirit to the extent that various changes can be made.

1 is an embodiment of a waste heat recovery type ventilation device and a control device thereof.

Figure 2 is a flow chart showing the operation control method of the conventional waste heat recovery type ventilator.

Figure 3 is an embodiment showing a sleep operation control device of the waste heat recovery type ventilation apparatus according to the present invention.

Figure 4 is a flow chart showing a method for controlling the sleep operation of the waste heat recovery type ventilation apparatus according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: waste heat recovery ventilator 110: exhaust fan

111: indoor exhaust damper 112: outdoor exhaust damper

120: heat exchanger 121: exhaust filter

122: air supply filter 130: air supply fan

131: outdoor air supply damper 132: indoor air supply damper

200: room remote control 210: pollution detection sensor

220: Ambient light sensor 230: Indoor / outdoor temperature sensor

Claims (5)

When the user operates the room remote controller 200 to turn on the waste heat recovery type ventilation device 100 (S10 ′), the room remote controller 200 optimizes indoor air while the user minimizes noise according to the human sleeping pattern. A first step (S11 ') of determining whether the sleep mode is selected to condition the air; As a result of determining whether the sleep mode is selected, if the sleep mode is selected, the room remote controller 200 determines whether the pollution degree of the current indoor air detected by the pollution degree sensor 210 is greater than or equal to a preset pollution determination value. Process S12 '; As a result of determining the pollution degree in the second process, if the pollution degree of the current indoor air is less than the pollution determination value, the third process S13 ′ stops the operation of the exhaust fan 110 and the air supply fan 130 and returns to the second process. ; As a result of determining the pollution degree in the second process, if the pollution degree of the current indoor air is more than the pollution determination value, the room remote controller 200 determines whether the current indoor illumination intensity detected by the illumination sensor 220 is less than or equal to the predetermined sleep determination value. A fourth step (S14 ') of determining and returning to a first step (S11') if the illuminance of the current room is greater than the sleep determination value; And If the illuminance determination result in the fourth process, the current room illuminance is less than the sleep determination value, after the sleep waiting time set in advance by the room remote controller 200 has elapsed (S15 '), shallow sleep during the user setting time, heavy sleep The exhaust fan 110 and the air supply fan 130 of the waste heat recovery type ventilation device 100 according to the human sleep pattern repeating four sleep patterns, such as deep sleep and REM (Rapid Eye Movement) sleep. A fifth process S16 ′ of controlling the opening and closing of the exhaust dampers 111 and 112 and the air supply dampers 131 and 132 while controlling the output to a predetermined value and returning to the first process S 11 ′; Sleep operation control method of the waste heat recovery type ventilator characterized in that consisting of. The exhaust damper of the waste heat recovery type ventilation device (100) according to claim 1, wherein in the fifth process (S16 '), after the sleep waiting time has elapsed (S15'), the room remote controller 200 firstly sleeps during the shallow sleep time. With the (111, 112) open and the air supply dampers (131, 132) closed, the output of the exhaust fan 110 is increased from the minimum (MIN) of 10% to the maximum (MAX) of 40% and the ventilation is performed. When the indoor / outdoor temperature difference detected by 230) becomes 4 ° C or higher, that is, when the indoor temperature is 4 ° C or higher than the room temperature when indoor air cooling, or when the indoor temperature is 4 ° C or higher than the outdoor when indoor air heating, Surface operation control method of the waste heat recovery type ventilator characterized in that to stop the operation of the exhaust fan (110) in order to minimize the heat loss of the air. The method of claim 2, wherein in the fifth process (S16 '), after the sleep waiting time has elapsed (S15'), the room remote control 200 first operates the waste heat recovery type ventilation device 100 during the first shallow sleep time. After the control is performed, the output of the exhaust fan 110 is minimized (MIN) 40 with the exhaust dampers 111 and 112 and the air supply dampers 131 and 132 of the waste heat recovery type ventilator 100 opened for the second heavy water surface time. % To max. 60% and increase the output of air supply fan 130 to 10% to max. 40% from MIN to 40%. Ventilation is performed by the indoor / outdoor temperature sensor 230 during ventilation. When the detected indoor / outdoor temperature difference is 10 ° C or higher, that is, when the outdoor temperature is 10 ° C or higher than the room temperature when the indoor air is cooled, or when the indoor temperature is 10 ° C or higher than the outdoor when the air is heated, the indoor air heat loss. In order to minimize the operation of the air supply fan 130 and stop the air supply damper (1) 31, 132) the method of controlling the sleep operation of the waste heat recovery type ventilation apparatus. The method of claim 3, wherein in the fifth process (S16 '), after the sleep waiting time has elapsed (S15'), the room remote controller 200 controls the operation of the waste heat recovery type ventilation device 100 for the second heavy sleep time. After performing the operation, while the exhaust dampers 111 and 112 and the air supply dampers 131 and 132 of the waste heat recovery type ventilator 100 are opened for the third deep sleep time, the output of the exhaust fan 110 is minimized (MIN) by 60%. Sleep operation of the waste heat recovery type ventilator characterized by increasing the maximum (MAX) to 90% and increasing the output of the supply fan 130 from the minimum (MIN) 40% to the maximum (MAX) 90% Control method. The method of claim 4, wherein in the fifth process (S16 '), after the sleep waiting time has elapsed (S15'), the room remote controller 200 controls the operation of the waste heat recovery type ventilation device 100 during the third deep sleep time. Fourth, the output of the exhaust fan 110 and the air supply fan 130 in the state in which the exhaust dampers 111 and 112 and the air supply dampers 131 and 132 of the waste heat recovery type ventilation device 100 are opened during the REM sleep time. Ventilation is performed by reducing the maximum from 90% to the minimum 10%, and when the indoor / outdoor temperature difference detected by the indoor / outdoor temperature sensor 230 becomes 10 ° C or more during ventilation, that is, when the indoor air is cooled, If the temperature is 10 ° C. or higher than the room temperature or the room temperature is 10 ° C. or higher than the outdoor when the room air is heated, the operation of the air supply fan 130 is stopped and the air supply dampers 131 and 132 are minimized to minimize heat loss of the indoor air. Waste heat recovery type ventilation characterized by closing Sleep operation control method value.

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