KR20090008112U - Air conditioner system - Google Patents

Abstract

The present invention relates to an air conditioning system, and in particular, the present invention detects the user's biological signal to grasp the emotional state of the user, and if the user feels uncomfortable, according to the air conditioning control factor until the user feels comfortable. By sequentially changing, it is possible to perform comfortable air conditioning control according to the user's physical characteristics and mood state.

Description

Air Conditioning System {AIR CONDITIONER SYSTEM}

The present invention relates to an air conditioning system, and more particularly, to an air conditioning system capable of grasping a user's emotional state and performing comfortable air conditioning control accordingly.

In general, an air conditioner is a device used for indoor cooling or heating purposes, and a refrigeration cycle that performs a normal heat exchange action is applied. Normally, the liquid is vaporized when the pressure is kept constant and the temperature is raised, and the vaporized gas is liquefied when the pressure is kept constant and the temperature is decreased. Therefore, the heat exchange action means cooling or heating by utilizing the property of absorbing the surrounding heat when the liquid evaporates and releasing the heat when liquefied.

In addition to improving the living environment, many homes use air conditioners to heat or cool the room to a comfortable temperature.

In operating the air conditioner, it is preferable to automatically adjust the air conditioning control factors so that the user does not feel uncomfortable.

In the air conditioner disclosed in Japanese Patent Application Laid-open No. Hei 9-303842, the user's physiological amount is detected through a physiological amount detection means worn on a user's wrist, and the user's comfort is determined and the temperature is adjusted accordingly. Providing an environment is disclosed.

Users who use the air conditioner may feel comfortable or uncomfortable depending on what kind of air conditioning control factors are controlled according to physical characteristics or mood conditions. In other words, the user may feel comfortable by controlling the temperature of the air stream discharged according to the user's physical characteristics and mood, or may feel comfortable by controlling the wind direction and the air volume of the air stream instead of the temperature control.

However, in the related art, since only the air conditioning control factor of the temperature control is controlled, in some cases, the user may not feel comfortable and may feel uncomfortable, and thus there is a problem in that the air conditioning control that is optimal for the user's physical characteristics or mood is not possible.

Accordingly, an object of the present invention is to provide an air conditioning system that can change various air conditioning control factors sequentially until the user feels comfort by grasping the emotional state of the user from the bio signals of the user. will be.

The air conditioning system of the present invention for achieving the above object is a biological sensing device for detecting a user's bio-signal, the user's emotional state is determined based on the bio-signal, and the user's emotional state is unpleasant And an air conditioner for sequentially changing a plurality of air conditioning control factors according to priorities until the emotional state of the user becomes a feeling of comfort.

Here, the plurality of air conditioning control factors may include at least two of wind direction control, air volume control, and temperature control.

Here, the priority is characterized in that the input by the user.

Here, the biometric sensing device is characterized in that it detects the bio-signal in contact with the body part of the user.

According to the present invention, by detecting a user's biological signal to grasp the emotional state of the user, and if the user feels uncomfortable, by changing the air conditioning control factors in order according to the priority until the user feels comfortable, There is an effect that can perform a comfortable air conditioning control according to the mood.

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

1 is a block diagram of an air conditioning system according to an embodiment of the present invention. FIG. 2 illustrates a control block diagram of the biosignal sensing apparatus shown in FIG. 1. 3 is a side cross-sectional view of the air conditioner shown in FIG. 1.

As shown in Figures 1 to 3, the air conditioning system according to an embodiment of the present invention comprises a bio-signal detection device 10 and the air conditioner 20.

The biosignal detecting apparatus 10 detects a biosignal such as an optical pulse wave and an electrocardiogram of a human body and wirelessly transmits the biosignal to the air conditioner 20.

The biosignal detection device 10 includes a volumetric pulse wave sensor 11 for measuring the photoelectric pulse wave of the human body, an electrocardiogram sensor 12 for measuring the electrocardiogram of the human body, photo-specific pulse wave information and electrocardiogram information detected by each sensor, and the like. A control unit 13 for controlling the biosignal to be transmitted to the air conditioner 20, and an interface unit for wirelessly transmitting the biosignal in communication with the air conditioner 20 according to the control signal of the control unit 13 ( 14).

The photoelectric pulse wave sensor 11 includes a photoelectric sensor including a combination of an infrared diode and a phototransistor, and measures and outputs a photoplethysmogram (PPG) indicating a volume change of a peripheral blood vessel.

The ECG sensor 12 includes a plurality of electrodes, and each electrode is attached to an appropriate part of the human body to measure and output an electrocardiogram (ECG) generated in the human body. Electrocardiogram refers to a waveform detected by detecting a bioelectricity representing the electrical activity of the heart during the heartbeat cycle. The bioelectric is an action potential that occurs when the heart muscle contracts and relaxes, causing an electric current to spread from the heart to the body, and this electric current generates a potential difference according to the position of the body.

As will be described later, heart rate variability (HRV) can be calculated using biosignal signals such as volumetric pulse wave and electrocardiogram, and the heart rate variability can be analyzed by power spectrum analysis or other analysis techniques to provide a user with a comfortable feeling. It is possible to know whether it is a feeling state or an unpleasant state. Heart rate variability refers to the degree of change in the time of the heartbeat when the human body continuously changes the heartbeat in order to maintain homeostasis of the body against external influences, and thus the user's emotional state can be identified.

The biological signal detecting device 10 is formed as a watch band that can be supported on the wrist or ankle to be worn on the wrist or ankle as an example of a user's body part.

Meanwhile, the air conditioner 20 uses the biosignal provided from the biosignal detection apparatus 10 to determine an emotional state such as whether the user feels comfortable or unpleasant, and the user feels unpleasant. In this case, various air conditioning control factors such as wind direction control, air volume control, temperature control, humidity control, etc. are changed in order according to priority until the user feels comfortable. To perform.

As shown in FIG. 3, the air conditioner 20 includes a box-shaped body 21 having an open front surface. An open front surface of the main body 21 is provided with a front panel 22 covering the front surface. It is installed inside the main body 21 and includes a heat exchanger 23 for heat exchange and a blower fan 24 for blowing air.

First and second suction holes 25 are formed on both sides of the lower part of the main body 21 to suck the indoor air into the cabinet 21, and the upper part of the front panel 22 of the main body 21 is provided with air harmonized therein. A discharge port 26 for discharging back to the indoor space is formed.

Inside the discharge port 26, left and right louvers 27 for guiding the direction of the discharged air from side to side and up and down louvers 28 for guiding up and down are provided.

On the lower side of the discharge port 16, the human body sensor 29 is installed to reciprocate from side to side in a predetermined angle range. The human body sensor 29 includes an infrared distance sensing element and an infrared temperature sensing element, and is provided to be rotatable by a motor. The human body sensor detects the presence or absence of a human body by detecting a distance from an obstacle in an indoor space in a rotating direction and a space temperature in a rotating direction. As will be described later, the human body sensor is used to control air conditioning control factors such as wind direction control, air volume control, temperature control depending on the presence of a person.

The heat exchanger 23 inside the main body 21 is installed to have a predetermined inclination inside the upper space so that air passing through the inside may be heat exchanged. The blower fan 24 is installed in the inner lower space of the main body 21, and the air sucked into the main body 21 through the suction ports 25 on both sides thereof discharges through the upper heat exchanger 23. Blow into the air.

The configuration of the air conditioner is that the air sucked into the main body 21 through the inlet port 25 when the blower fan 24 operates is heat exchanged through the heat exchanger 23 of the upper portion inside the main body 21 By supplying it back to the indoor space through the upper discharge port 26, it is to allow the indoor air to be heated and cooled.

As shown in FIG. 4, the air conditioner 20 according to the embodiment of the present invention having the above-described configuration includes a controller 33 for performing overall control.

On the input side of the control unit 33, a sensor unit 32 including an interface unit 31 for transmitting and receiving information of the biosignal detection device 10, an input unit 38 for receiving a user's command, and various sensors of an air conditioner ) Is electrically connected.

On the output side of the controller 33, a fan driver 34 for driving the blower fan 24, a louver driver 35 for driving the left and right louvers 27 and the upper and lower louvers 28, and a compressor 37 The compressor drive part 36 is electrically connected. In addition, a motor for rotating the human body sensor is electrically connected.

The control unit 33 receives a biosignal such as photoelectric wave information and electrocardiogram information from the biosignal detection device 10, and calculates an interval between the highest peaks of the biosignal using the received biosignal and determines the HRV (HRV). ) And frequency conversion analysis to analyze the power spectrum. The control unit 33 determines whether the emotional state of the user feels comfortable or uncomfortable through the power spectrum analysis. If the user feels uncomfortable, the control unit 33 determines whether the user feels comfortable while sequentially changing various air conditioning control factors according to the priority until the user feels comfortable, and if the user feels comfortable, Maintain current control for the time. Then, the control is continuously performed while determining whether the user feels uncomfortable. The priority of the various air conditioning control factors may be set in advance or may be input from the user through the input unit 38.

When the air direction control is performed among the various air conditioning control factors, the air flow direction control is performed by moving the left and right louvers 27 and the upper and lower louvers 28 through the louver driving unit 35. At this time, the control unit 33 continuously changes the current discharge direction to direct wind (or indirect wind) while judging the emotional state of the user, and if it is still unpleasant through this, changes to indirect wind (or direct wind). Perform sequential wind direction control.

In addition, in the case of performing air volume control among various air conditioning control factors, the air volume of the air discharged by controlling the rotational speed of the blower fan 24 through the fan driving unit 34 is sequentially changed from the strong wind to the low wind or the low wind to the strong wind. To control. At this time, the control unit 33 continuously determines the emotional state of the user while changing the current discharge wind volume to strong winds (or low winds), and even through this sequential wind volume control such as changing to low winds (or strong winds) Perform

In addition, in the case of performing temperature control among several air conditioning control factors, the operation rate of the compressor 37 is controlled by the compressor driver 36 to control the room temperature from high temperature to low temperature or from low temperature to high temperature within a predetermined range of the set temperature. Control sequentially. In this case, the controller 33 continuously changes the temperature from the high temperature to the low temperature while judging the emotional state of the user, and if it still feels uncomfortable, performs the sequential temperature control such as changing from the low temperature to the high temperature.

Hereinafter, the operation of the control unit 33 will be described in more detail with reference to FIG. 5. In the above-described embodiment, the air conditioning control factor is limited to three cases such as wind direction control, air volume control, and temperature control. do.

First, the control unit 33 adjusts the intake air, and performs the air conditioning operation of discharging the conditioned air in a discharge direction set or preset by the user (S100).

After the air conditioning operation is performed, the bio signal is continuously received from the bio signal detecting apparatus 10 for a predetermined time (S110), and the heart rate variance is calculated using the received bio signal (S120).

After calculating the heart rate variability, analytical methods such as power spectrum analysis of the heart rate variability are performed (S130), and through this, the emotional state of the user such as whether the user feels unpleasant or comfortable is determined (S140). . If the user feels comfortable, the air conditioning control factor currently being controlled is maintained (S150).

On the other hand, if the user feels uncomfortable, first, the wind direction control is performed according to the priority of the air conditioning control factor (S160). When controlling the wind direction, move the left and right louvers 27 and the upper and lower louvers 28 to indirect wind to discharge the harmonic air from the direct wind to discharge the harmonic air from the direct air to the place where there is no person, or indirectly. It controls sequentially from the wind to the direct wind for a certain time.

During the wind direction control, the bio signal is continuously received from the bio signal detecting apparatus 10 for a predetermined time (S170), and the emotional state of the user is analyzed from the received bio signal (S180). Using the analysis result, it is again determined whether the user feels comfortable (S190). If the user changes the comfort state through the wind direction control, the wind direction control currently being controlled is performed for a predetermined time.

On the other hand, if the user continues to feel discomfort even through the wind direction control, the air volume control which is a priority after the wind direction control is performed (S200). In controlling the air volume, the air speed of the air discharged by controlling the rotational speed of the blower fan 24 is sequentially controlled from the strong wind to the low wind or from the low wind to the strong wind.

While performing the air volume control, the bio signal is continuously received from the bio signal detecting apparatus 10 for a predetermined time (S210), and the user's emotional state is analyzed again from the received bio signal (S220). Using the analysis result, it is again determined whether the user feels comfortable (S230). If the user changes the comfort state through the airflow control, the airflow control currently being controlled is performed for a predetermined time.

On the other hand, if the user continues to feel discomfort even through the wind direction control, temperature control which is a priority after the air volume control is performed (S240). During temperature control, the operation rate of the compressor 37 is controlled to sequentially control the room temperature from high temperature to low temperature or from low temperature to high temperature within a predetermined range of the set temperature.

During the temperature control, the biosignal is continuously received again from the biosignal sensing apparatus 10 for a predetermined time (S250), and the user's emotional state is analyzed again from the received biosignal (S260). Using the analysis result, it is again determined whether the user feels comfortable (S270). If the user changes comfort state through the air volume control, the temperature control currently being controlled is performed for a predetermined time.

On the other hand, if the user continues to feel uncomfortable even through temperature control, the process returns to step S110 to continue the following steps.

In the above-described embodiment, only the individual air conditioning control factors such as wind direction control, air volume control, and temperature control are described. However, the present invention is not limited thereto and two or more air conditioning control factors may be performed together. This is possible by selecting a combination of air conditioning control factors when the user prioritizes the air conditioning control factors.

1 is a block diagram of an air conditioning system according to an embodiment of the present invention.

FIG. 2 is a control block diagram of the biosignal sensing apparatus shown in FIG. 1.

3 is a side cross-sectional view of the air conditioner shown in FIG. 1.

4 is a control block diagram of the air conditioner shown in FIG. 1.

5 is a control flow diagram for explaining the operation of the air conditioning system according to an embodiment of the present invention.

* Description of the symbols for the main functions of the drawings *

10: biosignal detection device 20: air conditioner

31: interface unit 32: sensor unit

33: input unit 34: fan drive unit

35: louver driving unit 36: compressor driving unit

Claims (4)

A biometric sensing device for sensing a biosignal of a user; Determining the emotional state of the user based on the bio-signal, and if the emotional state of the user feels uncomfortable, the plurality of air conditioning control factors in order according to the priority until the emotional state of the user becomes a feeling of comfort Air conditioning system comprising an air conditioner for changing to. The method of claim 1, The air conditioning system includes at least two of wind direction control, air volume control, and temperature control. The method of claim 1, And said priority is input by a user. The method of claim 1, The bio-sensing device detects the bio-signal by contacting a user's body part.

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