KR101248746B1 - Sleeping drive control method of Air conditioner - Google Patents

Abstract

The present invention relates to a method of controlling a sleep operation of an air conditioner. The present invention determines whether the sleep operation is performed, and sequentially performs a plurality of sub-modes of the sleep operation during the sleep operation.

Air Conditioner, Bedtime Operation, Room Temperature

Description

Sleep driving control method of air conditioner {Sleeping drive control method of Air conditioner}

The present invention relates to a sleep operation control method for an air conditioner, and more particularly, to a sleep operation control method for an air conditioner for automatically changing a room temperature so that a user takes a good night's sleep during sleep operation.

In general, the air conditioning operation of the air conditioner creates a more comfortable indoor environment by cooling and heating indoor air at a room setting temperature selected by a user. However, since the cooling operation at bedtime only operates at the initial set temperature, the user feels cold after a time, and when the cooling operation is stopped, the user feels heat and thus provides a comfortable sleeping environment. On the contrary, since the heating operation at the time of sleep only operates at the initial set temperature, the user feels heat after a time, and when the heating operation is stopped, the user feels cold and there is a limit in providing a comfortable sleeping environment.

FIG. 1 is a sleep state characteristic diagram in which NON REM SLEEP and REM SLEEP are periodically displayed. As shown in FIG. 1, humans are approximately 4-5 times overnight, approximately 90 minutes. By repeating Non REM SLEEP and REM SLEEP, you can see that the non-ram sleep at the time of elevation is the deepest. On the other hand, the sense of human hanseo is determined by the amount of metabolism and calorific value from the skin, and if the metabolic rate decreases, the cold will feel strongly. Figure 2 is a characteristic diagram showing the change in the metabolic rate of human from elevation to wake up. As shown in Figure 2, after elevation, human metabolism begins to decrease and becomes a non-rem sleep state. When falling into the body temperature drops markedly, accompanied by a severe sweating phenomenon. This sweating makes it difficult for humans to feel hot and unpleasant to go to deep sleep.

In this regard, Japanese Patent Application Laid-Open No. 2004-92918 (air conditioner) sets an indoor temperature at an initial stage during a pre-set bedtime operation in a cooling operation in consideration of characteristics of the human sleep state of FIG. Lower than the temperature allows the user to fall asleep quickly. And when the user falls into sleep, the metabolic rate and activity decreases, making the user feel cold easily.

However, the conventional bedtime control method of the air conditioner does not consider the bedtime operation time desired by the user, and the bedtime operation control is made based on the average bedtime time of 8 hours.

In addition, during the bedtime operation, the room temperature is higher than the set temperature in the second half, thereby increasing the skin temperature of the user, thereby causing the user to have a comfortable sleep.

In addition, the conventional bedtime operation of the air conditioner is provided only in the cooling operation, there is a problem that does not meet the desire of the user who wants to go to bed operation during the heating operation.

The present invention is to solve the above-mentioned problems, an object of the present invention is to provide a bedtime operation control method of the air conditioner to automatically change the room temperature during bedtime operation so that the user to take a good night's sleep.

The present invention for achieving the above object is determined whether the sleep operation, and sequentially performing a plurality of sub-modes to achieve the sleep operation during the sleep operation.

The plurality of sub-modes may include an elevation mode that lowers an indoor temperature by a first temperature than an indoor set temperature, and a wake-up mode that raises the indoor temperature by a second temperature from the indoor set temperature.

The plurality of sub-modes may further include a sound sleep mode in which the indoor temperature is periodically increased by a first temperature from the indoor set temperature and lowered to the indoor set temperature during a cooling operation.

The plurality of sub-modes may further include a sound sleep mode that maintains a state lowered by a first temperature than the indoor set temperature during heating operation and increases to the indoor set temperature.

In addition, when the deep sleep mode reaches the indoor set temperature, the process of lowering by the second temperature and then raising the indoor set temperature again is repeated.

In addition, the operation time of the deep sleep mode is determined according to the sleep operation time.

In addition, during the cooling operation, the second temperature is greater than the first temperature.

In addition, when the sleep operation command is input in the elevation mode during the cooling operation, the air conditioner is directly operated at a temperature lower by the first temperature than the indoor set temperature.

In addition, the second temperature during the heating operation is characterized in that less than the first temperature.

In addition, when the sleep operation command is input in the elevation mode during the heating operation, the air conditioner operates at the indoor set temperature for a predetermined period and then operates at a temperature as low as the first temperature.

In another aspect, the present invention provides a sleep operation control method operating in a cooling operation, comprising: an elevation mode in which an indoor temperature does not exceed an indoor set temperature until a first reference time, and periodically when the sleep operation exceeds the first reference time. And a sleep mode in which an indoor temperature is raised above the indoor set temperature and lowered to the indoor set temperature, and a wake-up mode in which the indoor temperature is maintained higher than the indoor set temperature if the first reference time remains.

In addition, the first reference time is characterized in that 1 hour.

In addition, the indoor set temperature is set within 24 to 27 degrees.

In addition, the indoor temperature is maintained at 2 degrees lower than the indoor set temperature until the first reference time, and when the indoor reference temperature is exceeded, the indoor temperature is periodically increased by 2 degrees from the indoor set temperature. When the first reference time remains, the indoor temperature is maintained at a temperature of 2.5 to 3 degrees higher than the indoor set temperature.

In addition, the present invention is a bed operation control method operating in a heating operation, the room temperature is maintained by the first temperature lower than the room set temperature until the first reference time, and the remaining sleep operation when the bed operation exceeds the first reference time The room temperature is raised by a second temperature over the room set temperature for a time.

In addition, the indoor set temperature is set within 22 to 25 degrees.

The first temperature is 2 degrees and the second temperature is 1 degree.

As described in detail above, the present invention is to adjust the room temperature to the change in the human sleep cycle and body temperature to allow the user to take a comfortable sleep.

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

As shown in FIG. 3, the air conditioner according to the exemplary embodiment of the present invention measures an input unit 10 for receiving operation information such as a cooling or heating operation mode, a sleeping operation time, an indoor set temperature, and an indoor temperature from a user. The temperature sensor 20, the input unit 10 receives the operation information is composed of a microcomputer 30 for controlling the sleep operation. In addition, the compressor 40 for discharging a high-temperature refrigerant, the compressor drive unit 50 for driving the compressor 40, the indoor fan 60 for blowing air heat-exchanged in an indoor heat exchanger (not shown), indoors It further includes an indoor fan drive unit 70 for driving the fan 60, a blade 80 for controlling the flow of the discharged air, a blade drive unit 90 for driving the blade 80.

The microcomputer 30 controls the driving unit according to the received driving information to control the sleep operation of the air conditioner. In addition, the microcomputer 30 receives the indoor temperature through the temperature sensor 20 when the sleep operation is started, and adjusts the indoor temperature by the sleep operation algorithm according to each operation mode.

If the user inputs the room setting temperature too low or high during sleep operation, the user may feel the heat or cold during sleep. In order to prevent this, during the cooling operation, the microcomputer 30 guides the display unit 100 to allow the user to set the indoor set temperature to 24 degrees to 27 degrees so that the user inputs the indoor set temperature within the temperature range. In addition, during the heating operation, the microcomputer 30 guides the display unit 100 to allow the user to set the indoor set temperature to 22 degrees to 25 degrees so that the user inputs the indoor set temperature within the temperature range. The reason why the range of indoor setting temperature varies depending on the driving mode is that the degree of body response varies according to seasonal temperature characteristics. For example, if the indoor and outdoor temperature difference between summer and winter is severe, it is susceptible to diseases such as colds. Therefore, during the sleep operation of the air conditioner, the indoor set temperature in summer is preferably set higher than the indoor set temperature in winter.

Sleep operation is divided into three sub-modes, which differ in operating time and room temperature. The sub-mode consists of a sleep mode to lower the room temperature so that the user quickly falls asleep, a sleep mode that controls the room temperature so that the user takes a good night's sleep, and a wake-up mode that increases the body temperature before the user wakes up.

The driving time of the sleep mode and the wake-up mode is set in the microcomputer 30, and the sleep time mode is set to the remaining time except the sleep time and the wake-up mode. For example, if the driving time of the elevation mode and the wake-up mode are set for 1 hour each, and the driving time input by the user is 8 hours, the driving time of the second section is 6 hours, and the driving time input by the user is 9 hours. If, the driving time of the second section is 7 hours.

In the microcomputer 30, the indoor set temperature data of each sub mode is set differently according to each operation mode. The indoor set temperature data is set in consideration of changes in body temperature and seasonal temperature characteristics corresponding to the human sleep cycle shown in FIGS. 1 and 2.

In the cooling mode, the indoor set temperature data in the elevation mode is set to lower the indoor temperature so that the user falls into a deep deep sleep (steps 3 and 4 of the non-rem) during the initial predetermined time of the sleep operation. When the user falls asleep, the amount of metabolism and activity decreases abruptly and the human body feels cold easily. Therefore, in the sleep mode, the indoor set temperature data is set to raise the room temperature to a certain temperature in order to provide a comfortable sleep state to the user. At this time, the elevated room temperature is set to repeatedly perform the operation of lowering the room temperature to the room setting temperature initially input by the user since the user acts as a factor that disturbs the comfortable sleep by making the user feel the heat. Lastly, when the user wakes up after going to bed, the user's body temperature is low, which prevents active physiological activity. Therefore, in the wake-up mode, the indoor set temperature data is used to increase the user's body temperature before the end of bedtime. It is set to raise further by a predetermined size.

In addition, the indoor set temperature data in the elevation mode in the heating operation is set to lower the indoor temperature so that the user falls into a deep deep sleep (steps 3 and 4 of the non-rem) during the initial predetermined time of sleep operation. At this time, since the indoor temperature in winter is often lower than the indoor set temperature input by the user, set the indoor temperature to be lowered after maintaining the indoor temperature at the indoor set temperature by operating the indoor set temperature input by the user for a predetermined time. do. In sleep mode, the indoor set temperature data keeps the lowered room temperature for a certain time so that the user can maintain a healthy human skin temperature during sleep in the winter, and gradually increases the room temperature during the remaining sleep time. It is set to increase until. Lastly, when the user wakes up after the end of bedtime operation, the user's body temperature is low, which prevents active physiological activity. It is set to raise further by a predetermined size.

Hereinafter, a method of controlling bedtime operation of an air conditioner according to an embodiment of the present invention will be described with reference to FIG. 4.

When the user inputs driving information for sleeping operation such as a driving mode, a sleeping operation time and an indoor set temperature through the input unit 10, the microcomputer 30 receives the input driving information (200).

When the microcomputer 30 receives the driving information in step 200, the microcomputer 30 determines whether an appropriate indoor set temperature according to the driving mode is input (210).

If the indoor set temperature is not a suitable indoor set temperature according to the operation mode in step 210, the microcomputer 30 sets the indoor set temperature to 24 to 27 degrees in the cooling mode and the indoor set temperature to 22 to 25 degrees in the heating mode. The display unit 100 is controlled to set, and the user is guided to input the indoor set temperature again within the temperature range (220).

If the indoor set temperature is a suitable indoor set temperature according to the operation mode in step 210, the microcomputer 30 allocates the operation time to each of the three sub-modes in consideration of the change in the body temperature corresponding to the sleep cycle of the human being input. (230).

When the operation time of each sub mode is allocated by the step 230, the microcomputer 30 adjusts the room temperature to 2 degrees lower than the room set temperature in the cooling mode to execute the elevation mode so that the user falls into the water. In the heating mode, the microcomputer 30 maintains the indoor temperature for a predetermined time for a predetermined time, and then adjusts the indoor temperature to 2 degrees lower than the indoor setting temperature to execute the elevation mode so that the user falls into the water quickly. In the elevation mode, the microcomputer 30 increases the capacity of the compressor 40 and the rotation speed of the indoor fan 70 such that the room temperature falls within a short time. When the room temperature is lowered, the skin temperature of the user is also lowered, allowing the user to sleep easily and fall into deep sleep in a short time (240).

After the operation time of the sleep mode, the microcomputer 30 determines that the user has fallen into sleep and executes a good sleep mode so that the user can take a good night's sleep. In the cooling mode, the microcomputer 30 executes a deep sleep mode in which the indoor temperature is increased by 2 degrees higher than the indoor set temperature, and the operation is repeated periodically to lower the indoor temperature. In the heating mode, the microcomputer 30 maintains the lowered indoor temperature for a predetermined time so that the user maintains a healthy human skin temperature during the winter sleep, and gradually increases the indoor temperature for the remaining sleep mode to set the user input. In operation 250, the sleep mode increases to the temperature.

After the operation time of the deep sleep mode, the microcomputer 20 determines that the user's wake up time is executed to execute the wake up mode. In the cooling mode, the microcomputer 30 executes a wake-up mode that raises the user's body temperature by raising the indoor temperature by 2.5 degrees or 3 degrees from the room set temperature and ends the operation. In the heating mode, the microcomputer 30 executes a wake-up mode in which the user's body temperature is increased by raising the indoor temperature by 1 degree from the room setting temperature and ending the work. As the room temperature increases, the user's body temperature increases and the user's physiological activity is activated (260).

Hereinafter, with reference to Figure 5 (a), (b) looks at the change in the room temperature according to the bedtime operation timing during the cooling operation of the air conditioner according to an embodiment of the present invention. When the sleep operation is started in FIG. 5 (a), the microcomputer 30 constantly blows air into the room for 0 to b hours at a temperature 2 degrees lower than the indoor set temperature Ts. At this time, the room temperature is drastically lowered for 0 ~ a hours, and the user's temperature control center is minimized because the user's skin temperature drops to an appropriate level. After that, the room temperature is kept constant for a ~ b hours to continuously lower the user's skin temperature to fall into sleep.

 During the b-c time, the microcomputer 30 gradually blows up the blowing temperature more than the blowing temperature between 0 and b in order to raise the room temperature to Ts + 2 degrees. At this time, the room temperature continuously rises slowly to prevent the human skin temperature from rising sharply, and the elevated room temperature prevents the skin temperature from falling so that the user takes a good night's sleep. During the c ~ e time, the microcomputer 30 increases the room temperature to Ts + 2 degrees in a wave shape and then lowers it to Ts so that the human skin temperature is in a comfortable range. If the room temperature is maintained at a high Ts + 2 degree for c ~ e hours, the user may feel heat and may be disturbed by a comfortable sleep. Therefore, it is necessary to operate the room temperature periodically.

 During the e-f time, the microcomputer 30 blows the room at a predetermined time at Ts + 2 degrees, and blows the air at a temperature higher than the predetermined temperature Ts + 2.5 degrees or Ts + 3 degrees. f is a time when the user wakes up, the room temperature is raised by a predetermined temperature further e-f time before a certain time to increase the user's body temperature, and helps the physiological activity to be active by this elevated body temperature.

Hereinafter, with reference to Figure 6 (a), (b) looks at the change in the room temperature according to the bedtime operation timing during the heating operation of the air conditioner according to an embodiment of the present invention.

When the sleep operation is started in FIG. 6 (a), the microcomputer 30 constantly blows air into the room at the indoor set temperature Ts input by the user for 0 to a time. At this time, the room temperature approaches Ts. Thereafter, the microcomputer 30 gradually lowers the blowing temperature for a to b hours so that the room temperature is Ts-2 degrees. As the temperature of the room decreases, the user's skin temperature drops to an appropriate level, thereby minimizing the operation of the user's temperature control center, which causes the user to fall asleep.

During the b ~ c time, the microcomputer 30 maintains a blowing temperature Ts-2 degrees such that the room temperature is continuously Ts-2 degrees, so that the user maintains a healthy human skin temperature during winter sleep. During the c ~ d time, the microcomputer 30 increases the blowing temperature every predetermined time so that the room temperature gradually increases to Ts. At this time, the room temperature continuously rises slowly to prevent the human body temperature from rising sharply, and the elevated room temperature prevents the skin temperature from falling so that the user takes a good night's sleep. Then, the air temperature is lowered to Ts-1 for the remaining sleep time, and the operation of increasing the temperature to Ts is repeated periodically so that the human skin temperature is in a comfortable range.

During the d ~ e time, the microcomputer 30 raises the blowing temperature to Ts + 1 so that the room temperature becomes Ts + 1. The e point in time is when the user wakes up, and thus increases the user's body temperature by increasing the room temperature further a predetermined temperature for a period of time d ~ e, and helps the physiological activity to be activated by the elevated body temperature.

FIG. 1 is a sleep state characteristic diagram in which NON REM SLEEP and REM SLEEP alternately appear periodically.

2 is a characteristic diagram showing a change in metabolic rate from elevation to wake up.

3 is a block diagram of an air conditioner according to an embodiment of the present invention.

4 is a flowchart illustrating a method for controlling sleep operation of an air conditioner according to an embodiment of the present invention.

Figure 5 (a) is a timing diagram of the sleep operation during the cooling operation of the air conditioner according to an embodiment of the present invention.

FIG. 5B is a timing diagram showing the room temperature in the sleep operation of FIG.

6 (a) is a timing diagram of bedtime operation during heating operation of an air conditioner according to an embodiment of the present invention.

6 (b) is a timing diagram showing the room temperature in the sleep operation of FIG. 6 (a).

Description of the Related Art [0002]

10: input unit 20: temperature sensor

30: microcomputer 40: compressor drive unit

50: indoor fan drive 60: blade drive

70: compressor 80: indoor fan

90: blade 100: display unit

Claims (17)

Determine if it is going to bed, In the sleep operation, a plurality of sub-modes that make up the sleep operation are sequentially performed, The plurality of sub-modes Elevation mode to lower the room temperature by the first temperature below the room set temperature, A deep sleep mode in which the indoor temperature is periodically increased by a first temperature from the indoor set temperature and lowered to the indoor set temperature during a cooling operation; and And a wake-up mode for raising the indoor temperature by a second temperature above the indoor set temperature. delete delete Determine if it is going to bed, In the sleep operation, a plurality of sub-modes that make up the sleep operation are sequentially performed, The plurality of sub-modes Elevation mode to lower the room temperature by the first temperature below the room set temperature, Maintains a state lower than the indoor set temperature by the first temperature during the heating operation, the sleep mode for raising to the indoor set temperature, And And a wake-up mode for raising the indoor temperature by a second temperature above the indoor set temperature. 5. The method of claim 4, The sleep mode is a sleep control operation method of the air conditioner, if the room temperature reaches the set temperature, the second temperature is lowered and then again increased to the room temperature set. The method according to claim 1 or 4, The operation time of the sleep mode is a sleep operation control method of the air conditioner is determined according to the sleep operation time. The method of claim 1, Sleeping operation control method of the air conditioner in the cooling operation the second temperature is larger than the first temperature. The method of claim 1, When the sleep operation command is input in the elevation mode during the cooling operation, the air conditioner is directly operated to a temperature lower by the first temperature than the room set temperature control method of the air conditioner. The method of claim 1, Sleeping operation control method of the air conditioner in the heating operation the second temperature is less than the first temperature. The method of claim 1, When the sleep operation command is input in the elevation mode during the heating operation, the air conditioner is operated at the indoor set temperature for a predetermined period of time and the temperature control operation of the air conditioner of the air conditioner is operated as low as the first temperature. In the sleep operation control method operating in the cooling operation, Elevation mode that keeps the indoor temperature not exceed the indoor set temperature by the first reference time, If the sleep operation exceeds the first reference time and the sleep mode to periodically increase the room temperature above the room temperature set to lower the room temperature, and And a wake-up mode for maintaining the indoor temperature higher than the indoor set temperature when the first reference time remains. The method of claim 11, The first reference time is 1 hour sleep control operation method of the air conditioner. The method of claim 11, The indoor set temperature is a sleep control operation method of the air conditioner is set within 24 to 27 degrees. The method of claim 11, Until the first reference time, the room temperature is kept 2 degrees lower than the room set temperature, When the first reference time is exceeded, the indoor temperature is periodically raised to 2 degrees above the indoor set temperature and lowered to the indoor set temperature. Sleeping operation control method of the air conditioner to maintain the room temperature is raised 2.5 ~ 3 degrees above the room set temperature when the first reference time remains. In the sleep operation control method operating in the heating operation, The indoor temperature is maintained by the first temperature lower than the indoor set temperature by the first reference time, Sleeping operation control method of the air conditioner for raising the room temperature by a second temperature than the room setting temperature for the remaining sleep operation time if the sleep operation exceeds the first reference time. 16. The method of claim 15, The indoor setting temperature is a bedtime operation control method of the air conditioner is set within 22 to 25 degrees. 16. The method of claim 15, The first temperature is 2 degrees, Sleeping operation control method of the air conditioner wherein the second temperature is 1 degree.

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