JP2002130765A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a comfortable sleeping environment, taking the human body-temperature balance into consideration. SOLUTION: An air conditioner is provided with a temperature sensor which detects the temperature in a room, a humidity sensor which detects the humidity inside of the room, and a heat balance calculating section which calculates the heat balance of the sleeping human body from the temperature and humidity in the room. The air conditioner calculates a wetted area ratio ω and a heat balance Q of the human body from the temperature, and humidity in the room and executes air conditioning, so as to maintain the wetted area ratio ω and heat balance Q at 0 and 0.06 (Q=0 and ω=0.06), respectively.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly to an air conditioner after going to bed.

[0002]

2. Description of the Related Art Various air conditioning controls have been proposed for comfortable air conditioning after going to bed. For example, JP-A-3-274
The control disclosed in Japanese Patent No. 345 considers a decrease in metabolic rate due to falling asleep, and gradually raises the room temperature in a plurality of times after a certain period of time after falling asleep. is there. The control disclosed in Japanese Patent Application Laid-Open No. 7-71804 reduces indoor humidity for a certain period of time after falling asleep because sweating is observed according to a change in metabolic rate after falling asleep.
After a certain period of time, the room temperature and the room humidity are increased.

[0003]

By the way, the human body maintains a thermal equilibrium state by controlling skin blood flow without distinction at the time of activity or sleep, and from the physiology of human body temperature control, a so-called thermal neutral state. Has been found to be the least burdensome condition for the human body. Also,
It is known that when the temperature falls outside the thermal neutral range due to heat or cold during sleep, REM sleep increases and frequent arousal occurs, resulting in deterioration of sleep quality. In addition, it has been pointed out that it is not appropriate to set the environmental temperature only by feeling comfortable before falling asleep in order to obtain a sufficient sleep. However, the conventional control focuses only on some physiological changes and thermal sensation, and does not consider the human body thermal equilibrium at all. Therefore, there has been a problem that sleep quality is easily deteriorated, and it is easy to cause awakening due to coldness or heat.

For example, as shown in FIG. 16, in the control disclosed in the above-mentioned Japanese Patent Application Laid-Open No. 3-274345, the cooling capacity of the air conditioner is reduced in order to raise the indoor temperature after a certain period of time from falling asleep. In such a case, the dehumidifying ability of the air conditioner also decreases, and the indoor humidity also increases. For this reason, there has been a problem that the thermal environment deviates from the thermal neutral area, resulting in insufficient heat radiation, causing the user to wake up hot at night.

On the other hand, as shown in FIG.
In the control disclosed in Japanese Patent Publication No. 1804, although not only the indoor temperature but also the indoor humidity is adjusted, the humidity adjustment is performed only with respect to perspiration, so that the body heat equilibrium state is changed with the change in temperature and humidity. In some cases, the person fell out of the neutral range, deteriorating sleep quality.

Heat radiation from the human body is broadly classified into non-evaporative heat dissipation due to convection, radiation and conduction affected by temperature and airflow velocity, and evaporative heat dissipation due to evaporation such as perspiration. Even if the ratio between the non-evaporative heat dissipation and the evaporative heat dissipation is different, if the sum of them is the same, the heat release amount will be the same value. It is said that there is no difference in thermal sensation if the heat radiation is the same during activities. However, during sleep, there is a physiological change such as sweating immediately after falling asleep, so that even if the heat radiation amount is the same, the sleep ratio will differ if the above ratio is different. Conversely, sleep quality can be improved by considering the balance between non-evaporative heat dissipation and evaporative heat dissipation. For example, when the body heat balance is the same, a low-humidity environment not only improves the physiological sleep quality but also improves the quality of the psychological element of falling asleep or awakening in a high-humidity environment. Also improve. In the conventional control, such a point was not taken into consideration at all.

[0007] The present invention has been made in view of the above, and an object of the present invention is to provide an air conditioner that provides a comfortable sleeping environment.

[0008]

In order to achieve the above object, according to the present invention, air conditioning is performed so that the heat balance of the sleeping human body becomes a predetermined value.

An air conditioner according to the present invention comprises an air conditioner main body for performing at least heating or cooling of room air and humidification or dehumidification of room air, temperature detecting means for detecting room temperature, and detecting room humidity. Humidity detecting means,
Control means for controlling the air-conditioning apparatus main body so that the sleeping person is in thermal equilibrium based on the temperature detected by the temperature detecting means and the humidity detected by the humidity detecting means.

According to the air conditioner, since the body heat balance of the sleeping person is stably maintained, a good sleep environment for improving the sleep quality is provided.

[0011] Another air conditioner according to the present invention is an air conditioner main body that performs at least heating or cooling of room air and humidification or dehumidification of room air, temperature detecting means for detecting room temperature, and room humidity. And a calculating means for calculating a heat balance of a sleeping person based on the temperature detected by the temperature detecting means and the humidity detected by the humidity detecting means, and the heat balance becomes a predetermined value. Control means for controlling the air conditioner main body as described above.

In the above air conditioner, air conditioning is performed so that the heat balance of the human body of the sleeping person becomes a predetermined value, so that the body heat balance of the sleeping person is stably maintained. for that reason,
A good sleep environment for improving sleep quality is provided.

Another air conditioner according to the present invention comprises: an air conditioner main body for performing at least heating or cooling of indoor air and humidification or dehumidification of indoor air; and a physiological amount detecting means for detecting a physiological amount of a sleeping person. A calculating means for calculating a heat balance of a sleeping person based on the physiological amount; and a control means for controlling the air-conditioning apparatus main body such that the heat balance becomes a predetermined value. It is.

According to the air conditioner, since the heat balance is calculated based on the physiological amount of the sleeping person, the calculation accuracy of the heat balance increases. Therefore, body heat balance can be realized more accurately.

The physiological amount detecting means may be a sensor worn on a part of a sleeping person's body (for example, an arm or a finger). For example, the physiological amount detecting means may include a blood flow sensor for detecting a blood flow.

The blood flow in the peripheral part of the human body increases when heat radiation is promoted outside the thermal neutral region, and conversely,
It is less when the heat radiation is suppressed outside the thermal neutral region. By detecting the blood flow with the blood flow sensor, the heat balance can be accurately calculated.

Preferably, the control means is configured to control the air conditioner main body so that the heat balance becomes zero.

As a result, the amount of heat generated and the amount of heat radiation of the human body of the sleeping person are equalized, and the burden on the human body is minimized. Therefore, the body heat balance of the sleeping person is stably maintained, and the sleep quality is improved.

Another air conditioner according to the present invention comprises: an air conditioner main body for performing at least heating or cooling of room air and humidification or dehumidification of room air; temperature detecting means for detecting room temperature; Humidity detecting means for detecting the temperature, the calculating means for calculating the heat balance amount Q and the wetted area ratio ω of the human body of the sleeping person based on the detected temperature of the temperature detecting means and the detected humidity of the humidity detecting means, Control means for controlling the air conditioner main body such that the balance amount Q and the wetted area ratio ω become predetermined values, respectively.

It is preferable that the control means is configured to control the air conditioner main body so that the heat balance amount Q = 0 and the wet area ratio ω = 0.06.

Evaporative heat dissipation is classified into sweating and dead steam, and when the evaporative heat dissipation is only dead steam, the sleeping area of a sleeping person is about 6%. In the air conditioner, the temperature and humidity are adjusted so that the heat balance Q = 0 and the wet area ratio ω = 0.06, so that the body heat balance is maintained in the thermal neutral region. Therefore, a favorable sleep environment that improves sleep quality is provided.

Another air conditioner according to the present invention comprises: an air conditioner main body that performs at least heating or cooling of room air and humidification or dehumidification of room air; temperature detection means for detecting room temperature; And a calculating means for calculating a heat balance of a sleeping person based on the detected temperature of the temperature detecting means and the detected humidity of the humidity detecting means, and a heat balance of the sleeping person before falling asleep. Storage means for storing the amount of heat; and control means for controlling the air conditioner main body such that the heat balance of the sleeping person after falling asleep is equal to the heat balance before falling asleep.

The temperature and humidity conditions in the room are set to conditions suitable for the user (sleeper) before falling asleep. Therefore, it is considered that the heat balance before falling asleep is a value that matches the preference of the sleeping person. Therefore, by making the heat balance after falling asleep equal to the heat balance before falling asleep, it is possible to provide a sleeping environment that matches the sleeper's preference.

Another air conditioner according to the present invention is an air conditioner main body that performs at least heating or cooling of room air and humidification or dehumidification of room air, temperature detecting means for detecting room temperature, and room humidity. Humidity detecting means for detecting the temperature of the sleeping person based on the detected temperature of the temperature detecting means and the detected humidity of the humidity detecting means, the target value of the heat balance amount from outside Target value input means for inputting; and control means for controlling the air conditioner body so that the heat balance amount becomes the target value.

According to the above air conditioner, the user (sleeping person) can freely change the target value of the heat balance by the target value input means, so that the target value is set to a value corresponding to the individual difference of the sleeping person. Can be set as appropriate. for that reason,
Despite individual differences in the physical strength and constitution of the sleeping person (for example, differences in heat production capacity due to the difference in the amount of brown adipose tissue possessed), comfort ranging from infants to the elderly meets the characteristics of a wide range of people. A good sleeping environment can be provided.

The temperature detecting means may be configured to detect the temperature in the bed instead of the room temperature, and the humidity detecting means may be configured to detect the humidity in the bed instead of the room humidity.

Thus, since the heat balance and the like are calculated based on the temperature and humidity in the bed, the calculation accuracy of the heat balance and the like is increased. Therefore, body heat balance can be realized more accurately.

By the way, as described above, a low-humidity environment not only improves the physiological sleep quality, but also improves the quality of the psychological element of falling asleep or waking up.

[0029] Therefore, it is preferable that the control means performs control to lower the indoor humidity from before sleeping when the relative humidity does not fall below 40% for a predetermined time after the sleeping person falls asleep.

Since sweating tends to occur immediately after falling asleep, a more comfortable sleeping environment can be provided by reducing the indoor humidity immediately after falling asleep as described above. On the other hand, if the indoor humidity is lower than 40%, the oral cavity tends to dry, which may adversely affect the sleeping environment. Therefore, by keeping the indoor humidity at 40% or more, a comfortable sleeping environment can always be provided without imposing a burden on the body.

In general, during sleep, the first
-The amount of sweating is large in the second stage, the amount of sweating decreases in the third stage in which the body temperature has not completely decreased, and the amount of sweating further decreases in the fourth and subsequent stages in which the body temperature tends to increase,
Sweating tends to be insensitive to excretion only.

In view of this, the control means may perform control to decrease the indoor humidity after the sleeping person falls asleep and then gradually increase the indoor humidity.

Thus, the indoor humidity can be changed according to the frequency of occurrence of perspiration, so that a comfortable sleeping environment corresponding to physiological changes can be provided.

[0034] The air conditioner may include a sweat amount detecting means for detecting a sweat amount of the sleeping person, and the control means may perform control for adjusting the indoor humidity according to the sweat amount.

Thus, the sweat amount of the sleeping person is directly detected by the sweat amount detecting means, so that the humidity adjustment according to the sweat amount can be executed with higher accuracy.

The air conditioner body is configured to be able to change one or both of the amount and direction of the blown air, and the control means controls the heat balance of the human body of the sleeping person to a predetermined value. The configuration may be such that one or both of the flow rate and the wind direction of the air blown out of the air conditioner main body are adjusted.

As a result, not only the room temperature and the room humidity but also the airflow velocity near the sleeping person can be adjusted, so that the body heat balance can be easily maintained in the thermal neutral region, and a more comfortable sleep can be achieved. Environment can be provided.

The air conditioner main body is configured so that the temperature of the blown air can be changed freely, and the control means controls the blown air of the air conditioner main body so that the heat balance of the human body of the sleeping person becomes a predetermined value. It may be configured to regulate the temperature.

The temperature of the blown air affects the perspiration response. For example, sweating can be suppressed by adjusting the blown air temperature lower. On the other hand, if the blown air temperature is adjusted to be higher, a natural perspiration reaction can be promoted. Therefore, by adjusting the temperature of the blown air together with the indoor humidity, it is easy to maintain the body heat balance.

The air conditioner includes target value input means for inputting a target value of the room temperature or the room humidity from the outside. The control means controls the room temperature or the room humidity to become the target value and the sleeping person is controlled. The air conditioner body may be controlled so that the heat balance of the human body becomes a predetermined value.

Thus, the user sets the target value of the room temperature or the room humidity through the target value input means, thereby achieving the body heat balance while maintaining the room temperature or the room humidity at the user's desired value. it can. Therefore, it is possible to provide a comfortable sleep environment corresponding to the user's preference.

[0042]

As described above, according to the present invention, the air conditioning is performed so that the heat balance becomes a predetermined value in consideration of the body heat balance of the human body of the sleeping person. Can be reduced. Therefore, sleep quality can be improved. Furthermore, sleep quality can be further improved by taking into account the balance between evaporative heat dissipation and non-evaporative heat dissipation and reducing body humidity while maintaining body heat balance. Therefore, a comfortable sleeping environment can be provided.

[0043]

Embodiments of the present invention will be described below with reference to the drawings.

Embodiment 1 As shown in FIG. 1, an air conditioner (1) according to the embodiment is a room air conditioner provided in a bedroom. The air conditioner (1) can perform both the cooling operation and the heating operation, and also has a humidifying function and a dehumidifying function.

FIG. 2 is a block diagram of the air conditioner (1). The air conditioner (1) includes an air conditioner main body (11), a temperature sensor (12) for detecting an indoor temperature, a humidity sensor (13) for detecting an indoor humidity, and a heat balance calculating unit (14). A control unit (15). The air conditioner main body (11) includes a heat exchanger and a blower (not shown), and performs heating or cooling of room air and humidification or dehumidification of room air. Heat balance calculation unit (14), based on the indoor temperature and indoor humidity detected by the temperature sensor (12) and the humidity sensor (13),
This is a calculation unit that calculates the heat balance Q and the like of the human body of the sleeping person (2). The control section (15) is a section that executes control of the air conditioner body (11).

Although several methods are known for calculating the heat balance Q, any of the calculation methods may be adopted. In the present embodiment, the calculation method described in "Thermophysiology" edited by Akio Nakayama (Rigaku Corporation, 1981) is used.

In the above calculation method, the heat balance amount Q is obtained by calculating the indoor temperature Ta [° C.], the indoor relative humidity Rh [%], the average radiation temperature Th [° C.], the air flow velocity v [m / sec], Metabolic rate of human body M
[kcal / m ³ h] and thermal resistance of clothing Iclo [m ² h ° C / kcal]
Is calculated by That is, Q = Q (Ta, Rh, Th, v, M, Iclo), and the heat balance Q is expressed as a function of these six parameters.

In the present embodiment, the room temperature Ta and the room humidity Rh are determined by the temperature sensor (12) and the humidity sensor, respectively.
Directly detected by (13). However, for the other four parameters, the constant values or the room temperature Ta
Alternatively, it is given in advance as a function of the indoor humidity Rh.

The average radiant temperature Th is synonymous with the average radiant temperature, and refers to the average value of the radiant temperatures taking into account the distance and area of the ceiling, wall, floor and the like. For the average radiation temperature Th, a plurality of set temperatures may be provided in advance, and one of the set temperatures may be selected according to the season or the outdoor temperature. Alternatively, the temperature may be defined as a temperature obtained by adding a predetermined temperature to the room temperature Ta. For example, during the cooling operation, the average radiation temperature Th = the indoor temperature Ta + α (α = 1 to 2)
(A constant value of ° C.). When outside air temperature−room temperature Ta <5 ° C., Th = Ta + 1, and the outside air temperature−
For example, Th = Ta + 2 when the indoor temperature Ta ≧ 5 ° C. may be set based on the indoor / outdoor temperature difference.

The airflow velocity v may be a constant value, or may be a value that changes according to the rotation speed of the blower of the air conditioner body (11). For example, 0.2 ~ depending on the size of the room
A constant value may be selected from a numerical range of 0.4 m / s. Alternatively, a table in which the number of rotations of the blower and the measured value of the wind speed at the center of the room are prepared in advance, and the table may be appropriately selected based on the table.

The metabolic rate M may be, for example, 0.9 met assumed as a metabolic rate during sleep, or 1.0 to 1.1 me assumed as a resting metabolic rate before falling asleep.
It may be t.

The thermal resistance Iclo of the clothes may be a fixed value or may be appropriately selected from a plurality of set values according to the season or the outdoor temperature. For example, during a cooling operation, 0.3 clo may be set as summer pajamas. Alternatively, the parameter κ related to the outside air temperature
And Iclo = 0.3 + κ (where −0.1 ≦ κ ≦
0.3).

As described above, in this embodiment, the heat balance Q is approximately calculated as a function of the room temperature Ta and the room humidity Rh.

The values of the average skin temperature and the wet area ratio ω are
ASHRAE Trans Vol. 77, 1971,
Calculation was performed based on the method described in p247 to p262. However, it goes without saying that another method may be used. In the above method, the wet area ratio ω is ω = 0.
06 + 0.94 (Ersw / Emax). Here, Ersw is the effective evaporation heat dissipation due to sweat from the skin, and Emax is the maximum evaporation heat dissipation from the skin. The wet area ratio ω is always a value of 0.06 or more.

In order to improve sleep quality, sleepers (2)
It is important to reduce the burden on the body, and it is particularly preferable to maintain the body heat balance in the thermal neutral region. Here, the thermal neutral region is a region in which body heat balance can be achieved only by adjusting blood flow. While sweating becomes remarkable in a higher temperature range than the thermal neutral range, body shake occurs in a lower temperature range than the thermal neutral range. Body heat equilibrium refers to the balance between the amount of heat produced and the amount of heat released by the human body,
Specifically, it means that the heat balance Q of the human body becomes zero (Q = 0).

As described above, heat radiation from the human body is broadly classified into non-evaporative heat dissipation and evaporative heat dissipation, and evaporative heat dissipation is further divided into heat dissipation due to perspiration and heat dissipation due to insensitive evaporation. Can be In general, when no sweating occurs (when only insensitive ejaculation), the wet area ratio ω is 0.06 (about 6%).
It is about. Therefore, by setting the heat balance Q to zero and keeping the wet area ratio ω at about 6%, body heat balance can be achieved in the thermal neutral region.

In the present air conditioner (1), the air conditioner body (11)
Is the target temperature Tam for the room temperature and the room humidity, respectively.
And it operates so that it may be set to target humidity Rhm. The target temperature Tam and the target humidity Rhm are appropriately changed by the control unit (15).

Next, a specific control method will be described with reference to FIG. First, a room temperature and a room humidity are detected (step ST1). Next, the wet area ratio ω is calculated (step ST2), and then the heat balance Q is calculated (step ST3).

Next, in step ST4, it is determined whether or not the heat balance amount Q = 0 and the wet area ratio ω = 0.06. The wet area ratio ω when no sweating occurs is 0.0
6, the wetted area ratio ω does not become less than 0.06. Therefore, even when the room is too dry, the wet area ratio ω is 0.06. Therefore, when the determination result of step ST4 is YES, the target humidity Rhm is increased by 1% because there is a case where the body is in a state of heat balance but not yet sweating (step S4).
T5).

On the other hand, if the decision result in the step ST4 is NO, the process proceeds to a step ST6, where it is determined whether or not the heat balance amount Q <0. If Q <0, it is determined that the user feels cold, and the target temperature Tam is increased by 0.1 ° C. (step ST7).

If the decision result in the step ST6 is NO, the process proceeds to a step ST8, where it is determined whether or not the heat balance Q> 0. If Q> 0, it is determined that the user feels heat, and the target temperature Tam is reduced by 0.1 ° C. (step ST9).

If the decision result in the step ST8 is NO, a state where Q = 0 and ω> 0.06 (step ST1
0), which indicates that the body is in a state of equilibrium but sweating, so that the target humidity Rhm is reduced by 1% (step ST11).

As described above, according to the present air conditioner (1), air conditioning is performed so that body heat balance is achieved in the thermal neutral region, so that the burden on the body of the sleeping person (2) can be reduced. And a good sleeping environment can be provided. In addition, since air conditioning is performed so that the wet area ratio ω is about 6%, the amount of evaporative heat dissipation can be made an appropriate amount, and the sleep quality can be further improved.

In the above embodiment, the wet area ratio ω and the heat balance Q are calculated based on the room temperature and the room humidity. However, a temperature sensor and a humidity sensor are provided in the bed of the sleeping person (2). May be provided, and ω and Q may be calculated based on the temperature in the bed and the humidity in the bed. Since the temperature and humidity in the bed are the temperature and humidity near the human body of the sleeping person (2), the wet area ratio ω and the heat balance Q are more accurately calculated based on the temperature and the humidity in the bed. can do.

In the above embodiment, ω
Although the control of the air conditioner body (11) is performed so that = 0.06 and Q = 0, the body heat balance may be achieved by using other parameters. For example, body heat equilibrium may be achieved based on SET ^* (standard new effective temperature) adopted as the indoor environment reference temperature of the American Society for Air Conditioning (ASHRAE). The range of SET ^* = 22.2 to 25.6 ° C. represents a thermal environment region that satisfies 80% or more of the persons, and in this region, it is considered that the body thermal equilibrium is realized near the thermal neutral region. be able to. Then, ω =
The air conditioner body (11) may be controlled so that 0.06 and SET ^* = 22.2 to 25.6 ° C. In this case, the wet area ratio ω is calculated in the process of calculating SET ^* .

<Embodiment 2> An air conditioner (1) according to Embodiment 2 estimates a body heat equilibrium state based on a physiological quantity of a sleeping person (2) and executes air conditioning so as to bring about a body heat balance. Things.

Various physiological quantities can be used for estimating the body heat equilibrium state. In this embodiment, the body heat equilibrium state is estimated based on the peripheral blood flow of the sleeping person (2). As shown in FIG. 4, as a means for detecting the blood flow, a blood flow sensor (5, 6) attached to the finger or arm of the sleeping person (2)
Is used. As the blood flow sensors (5, 6), an ultrasonic sensor, a laser Doppler sensor, or the like can be used.

FIG. 5 is a diagram schematically showing the relationship between the environmental temperature and the amount of heat radiation. Line L1 shows the state when the blood vessel is contracted, and at this time, the blood flow is minimal. Environmental temperature is P1 (environmental temperature at the intersection of line L1 and line L)
In the region on the left side, increased metabolism and body shaking may occur. The line L2 shows the state when the blood vessel is expanded, and at this time, the blood flow becomes maximum. In a region where the environmental temperature is on the right side of P2 (the environmental temperature at the intersection of the line L2 and the line L), sweating occurs. According to FIG. 5, when the environmental temperature is constant, when the blood vessel dilates (line L2)
It can be seen that the heat release amount is larger in the case of vasoconstriction (line L1). The line L is a line showing a physiological response, and it can be seen that the heat release amount is kept constant by contraction or expansion of the blood vessels when in the thermal neutral region. From such physiological characteristics, the body heat equilibrium state can be estimated based on the blood flow.

As shown in FIG. 6, in the second embodiment, first, the blood flow of the sleeping person (2) is detected (step ST21).
Next, based on the blood flow, it is determined whether or not the physiological condition of the sleeping person (2) is in a thermal neutral state (step ST2).
2). As a result, in the case of YES, the target temperature Tam and the target humidity Rhm are not changed, and the operating state at that time is maintained. On the other hand, when the determination result of step ST22 is N
In the case of O, the process proceeds to step ST23, and it is determined whether or not the departure direction of the thermal neutral state is on the heat dissipation promoting side.

If the decision result in the step ST23 is NO, the process proceeds to a step ST24, where the target humidity Rhm is 5
It is determined whether it is less than 0%. If the result of the determination is YES, the target humidity Rhm is increased by 1% (step ST2).
6) If NO, the target temperature Tam is raised by 0.1 ° C. (step ST25).

On the other hand, if the decision result in step ST23 is YE
In the case of S, the process proceeds to step ST27, where the target humidity R
It is determined whether hm is greater than 50%. If the determination result is YES, the target humidity Rhm is reduced by 1% (step ST29), and if the determination result is NO, the target temperature Tam is reduced by 0.1 ° C. (step ST28).

According to the present embodiment, since the body heat equilibrium state is estimated based on the physiological quantity of the sleeping person (2), the body heat equilibrium state can be estimated with high accuracy. Therefore, body heat balance can be realized more accurately.

<Embodiment 3> Before falling asleep, the user (that is, the sleeping person (2)) can change the setting of the air conditioner (1) according to his / her preference. It can be said that this is the most comfortable heat balance for the user. For such a reason, the air conditioner (1) according to the third embodiment performs air conditioning so as to maintain the heat balance before falling asleep.

As shown in FIG. 7, the air conditioner (1) according to the third embodiment includes an air conditioner body (11), a temperature sensor (12), a humidity sensor (13), and a heat balance calculating section (14). , And control unit (15)
In addition, a heat balance storage unit (16) for storing the heat balance Qprev before falling asleep is provided.

As shown in FIG. 8, in the third embodiment, first, the heat balance amount Qprev of the sleeping person (2) before falling asleep is calculated and stored in the heat balance amount storage unit (16) (step). ST
31). Such storage of the heat balance Qprev may be performed only once, or may be performed at predetermined time intervals, and the stored value may be sequentially updated.

Next, it is determined whether or not the sleeping person (2) falls asleep (step ST32). A known method may be used for the determination of falling asleep, and it may be assumed that the user falls asleep after a certain period of time has passed since going to bed. For example, the light sensor may detect that the room is turned off, and may determine that the user has fallen asleep when the room is turned off or when a certain period of time has elapsed since the light was turned off. The time point when the sleep button on the remote control is pressed or the time point when the off timer is set may be assumed to be the time point of falling asleep. Alternatively, a point in time when a certain time elapses (for example, after 10 to 15 minutes) from the point in time when the sleep button on the remote controller is pressed or the point in time when the off timer is set may be assumed to be the point in time of falling asleep.

When it is determined that the sleeping person (2) falls asleep, the process proceeds to step ST33, and the heat balance Q of the sleeping person (2) is calculated (step ST33). Next, it is determined whether or not the heat balance amount Q matches the heat balance amount Qprev before falling asleep (step ST34). When the result of the determination is YES, the target temperature Tam and the target humidity Rhm are not changed, and the operating state at that time is maintained. On the other hand, if the determination result is NO, the process proceeds to step ST35, and it is determined whether the heat balance amount Q is larger than the heat balance amount Qprev before falling asleep.

If the decision result in the step ST35 is NO, it is determined whether or not the target humidity Rhm is less than 50% (step ST36). If the result is YES, the target humidity Rhm is increased by 1% (step ST38). , NO, the target temperature Tam is raised by 0.1 ° C. (step ST3)
7).

If the decision result in the step ST35 is YES, it is decided whether or not the target humidity Rhm is larger than 50%, and in the case of YES, the target humidity Rhm is reduced by 1% (step ST41), and NO , The target temperature Ta
m by 0.1 ° C.

According to the present embodiment, the heat balance Q after falling asleep of the sleeping person (2) can be maintained at the heat balance amount Qprev before falling asleep, so that the sleeping person (2) more fits the taste of the sleeping person (2). A sleeping environment can be provided.

<Embodiment 4> The sleeping person (2) has individual differences based on differences in physical strength and constitution (for example, differences in heat-producing ability due to differences in the amount of brown adipose tissue retained), and the like. The neutral range varies from person to person. Air conditioner according to Embodiment 4
In (1), an input means is provided for the user to change the target value of the heat balance in order to cope with the difference in the thermal neutral region due to individual differences.

As shown in FIG. 9, the air conditioner (1) according to the fourth embodiment includes an air conditioner body (11), a temperature sensor (12), a humidity sensor (13), and a heat balance calculating section (14). , And control unit (15)
Input section for inputting the target value of the heat balance in addition to (17)
It has. The input unit (17) may be provided on, for example, an operation panel or a remote controller of the air conditioner body (11). Also, input section
(17) may be configured to input the target value of the heat balance amount by a number, or may be configured so that the user performs an operation of relatively increasing or decreasing the target value.

In the present embodiment, air conditioning is performed so that the heat balance of the sleeping person (2) becomes the target value set via the input unit (17). Therefore, it is possible to provide a comfortable sleeping environment according to individual differences.

<Embodiment 5> Even if the total heat radiation of the sleeping person (2) is the same, the lower the indoor humidity, the better the quality of sleep. The air-conditioning apparatus (1) according to the fifth embodiment performs air-conditioning immediately after falling asleep, where sweating is likely to occur, such that the heat balance becomes a predetermined value while the indoor humidity is low.

As shown in FIG. 10, in this embodiment, first, a target value Qt of the heat balance is set (step ST51). The target value Qt may be set to zero as in the first or second embodiment (Qt = 0), or may be equal to the heat balance amount Qprev before falling asleep as in the third embodiment (Qt = Qpr).
ev), may be set by the user as in the fourth embodiment.

Next, it is determined whether or not the sleeping person (2) falls asleep (step ST52). When the sleeping person (2) falls asleep,
Change target humidity Rhm to 40% (step ST5)
3). Here, the reason for setting the target humidity Rhm to 40% is as follows.
This is because if the room humidity is lower than 40%, the mouth is dried, which is a factor of deteriorating sleep quality.

Next, the room temperature Ta is detected (step S).
T54), the indoor humidity Rh is detected (step ST5).
5). Then, the heat balance Q is calculated (step ST5).
6). Next, it is determined whether or not the calculated heat balance Q matches the target value Qt (step ST57). If the result of the determination is YES, the target temperature Tam is not changed.
If the result of the determination is NO, the process proceeds to step ST58.

Step ST58 and subsequent steps are steps for calculating a target temperature Tat such that the heat balance amount Q matches the target value Qt, and the target temperature Tat is repeatedly calculated. In step ST58, the room temperature maximum value T
This is a step of setting initial values of amax and the minimum indoor temperature value Tamin, where Tamax = 50 ° C. and Tamin = 0 ° C.
And Next, the process proceeds to step ST59, where the provisional target temperature Tav is calculated as an average value of the maximum room temperature Tamax and the minimum room temperature Tamin. That is, Ta
Let v = (Tamax + Tamin) / 2.

Next, the target temperature Tav and the room humidity Rh
From this, the heat balance Qp is calculated. This heat balance Qp
Is the heat balance when the room temperature is the target temperature Tav. After step ST61, Tav is corrected so that the heat balance Qp matches the target value Qt. In step ST61, it is determined whether or not the heat balance Qp is larger than the target value Qt, and YES
In this case, Tamax is updated to Tamax = Tav (step ST62). If the decision result in the step ST61 is NO, the process proceeds to a step ST63 to determine whether or not the heat balance amount Qp is smaller than the target value Qt. Step ST
If the judgment result in the step 63 is YES, Tamin is changed to Tamin.
= Tav (step ST64).

Then, in step ST65, it is determined whether or not the difference between the heat balance Qp and the target value Qt is equal to or less than a predetermined value. Specifically, it is determined whether or not the condition of | Qp−Qt | <0.1 is satisfied. As a result, in the case of YES,
It is determined that Qp and Qt are substantially equal, and the provisional target temperature Tav at that time is determined as the target temperature Tat,
So that the indoor humidity is 40% and the indoor temperature is Tat,
Perform air conditioning. On the other hand, if the decision result in the step ST65 is NO, the process returns to the step ST59 to set the target temperature Tav again.

As a result, according to the present embodiment, the room temperature, the room humidity, and the body heat equilibrium state of the sleeping person (2) change as shown in FIG. 11, for example. That is, when the sleeping person (2) falls asleep, the indoor humidity decreases and a low-humidity environment is provided. At this time, in order to balance body heat, the room temperature rises so as to correspond to a decrease in room humidity. As a result, the heat balance is maintained at a predetermined value, and body heat balance is achieved in the thermal neutral region.

<Embodiment 6> FIG. 12 is a diagram showing changes over time in the depth of sleep and the amount of perspiration during sleep. As can be seen from FIG. 12, certain physiological characteristics are seen during sleep,
The frequency of sweating changes periodically. The sixth embodiment focuses on such a temporal change in perspiration, and changes the indoor humidity according to the perspiration.

As shown in FIG. 13, in this embodiment, similarly to the fifth embodiment, first, a target value Qt of the heat balance is set (step ST71). Next, it is determined whether or not the sleeping person (2) falls asleep (step ST72). Sleeping person (2)
Falls asleep, the target humidity Rh depends on the elapsed time after falling asleep.
Change m. Specifically, first, it is determined whether or not the sleep time is less than 3 hours (step ST73), and if YES, the target humidity Rhm is set to 40% (step ST7).
4). In the case of NO, it is determined whether or not the sleep time is less than 6 hours (step ST75), and in the case of YES, the target humidity Rhm is set to 50% (step ST76). N
In the case of O, the target humidity Rhm is set to 60%. That is, the target humidity Rhm is gradually increased in accordance with the sleep time so that the target humidity Rhm increases as the sleep time increases.

Thereafter, detection of the room temperature Ta (step ST78) and detection of the room humidity Rh (step ST7).
9) to calculate the heat balance Q (step ST8).
0). Then, it is determined whether or not the heat balance Q is equal to the target value Qt (step ST81). If YES, the target temperature Tam is not changed, and the operating state at that time is maintained. On the other hand, if the decision result in the step ST81 is NO
In the case of, the target temperature is calculated by performing the same repetitive calculation as in the fifth embodiment (see steps ST58 to ST66). Then, air conditioning is performed so that the room temperature becomes the target temperature.

According to the present embodiment, it is possible to provide a high-quality sleep environment that flexibly responds to physiological changes during sleep.

Seventh Embodiment As shown in FIG. 14, the air conditioner (1) according to the seventh embodiment includes a perspiration sensor (18) for detecting the amount of perspiration, and the perspiration detected by the perspiration sensor (18). The target humidity Rhm is changed based on the amount.

As shown in FIG. 15, in this embodiment, similarly to the fifth embodiment, first, a target value Qt of the heat balance is set (step ST91). Next, it is determined whether or not the sleeping person (2) falls asleep (step ST92). Sleeping person (2)
When falls asleep, the target humidity Rhm is appropriately changed according to the amount of sweating. Specifically, first, it is determined whether or not the amount of perspiration is equal to or more than a first predetermined value (for example, 80% of the maximum detection value of the perspiration sensor (18)) (step ST93), and in the case of YES, the target humidity Rhm is set to 40. % (Step ST94). NO
In the case of, the amount of perspiration is equal to or more than a second predetermined value smaller than the first predetermined value (for example, 60% of the maximum detection value of the perspiration sensor (18)).
Is determined (step ST95), and if YES, the target humidity Rhm is set to 50% (step ST9).
7) If NO, set target humidity Rhm to 60% (step ST96). That is, the target humidity Rhm is changed in accordance with the amount of perspiration so that the target humidity Rhm decreases as the amount of perspiration increases.

Thereafter, detection of the room temperature Ta (step ST98) and detection of the room humidity Rh (step ST9).
9) to calculate the heat balance Q (step ST10).
0). Then, it is determined whether or not the heat balance Q is equal to the target value Qt (step ST101). If YES, the target temperature Tam is not changed, and the operating state at that time is maintained. On the other hand, if the decision result in the step ST101 is NO, a similar calculation as in the fifth embodiment (see steps ST58 to ST66) is performed to calculate the target temperature. Then, so that the indoor temperature becomes the target temperature,
Perform air conditioning.

According to the present embodiment, air conditioning is performed based on the amount of perspiration directly detected by the perspiration sensor (18), so that the accuracy of coping with physiological changes can be improved and higher quality can be achieved. A sleeping environment can be provided.

The perspiration sensor (18) may be attached to a part of the body of the sleeping person (2) (for example, a wrist, arm, chest or finger), or may be wrapped around a part of the body. It may be. Further, one or two or more sensors provided inside the duvet cover above the mattress may be provided. When two or more sensors are used, a detection error due to body movement such as rolling over can be reduced by regarding the larger detection value as the actual amount of perspiration.

<Other Embodiments> Each of the above embodiments is
Although the room temperature and indoor humidity were adjusted so that the heat balance reached a predetermined value, in addition to the room temperature and indoor humidity, one or both of the air volume and air direction of the air conditioner body (11) were adjusted. May be used. Thereby, the airflow velocity near the sleeping person (2) can be changed, and it becomes easy to bring about a body heat balance in the thermal neutral region.

The temperature of the air blown from the air conditioner body (11) may be adjusted. It is known that the temperature of the blown air affects the perspiration response, and that a cold stimulus by a low-temperature airflow suppresses perspiration. For example, even if the room temperature is the same, the amount of perspiration is lower when the blown air temperature is low. Conversely, when the blown air temperature is increased, a natural perspiration reaction can be promoted, and evaporative heat dissipation can be increased. Therefore, the same effect as the effect of lowering the indoor humidity can be obtained. The temperature of the blown air can be directly detected by a temperature sensor, or can be experimentally obtained from the indoor and outdoor temperatures, the air conditioning capacity of the air conditioner body (11), and the like. It can also be inferred from the relationship between the indoor temperature and the indoor heat exchanger temperature.

In the above embodiments, the room temperature and the room humidity are not set by the user, but the room temperature or the room humidity may be set by the user. The input unit for setting the room temperature or the room humidity may be provided in the air conditioner body (11) or the remote controller (not shown). This makes it possible to balance the body heat while maintaining the room temperature or the room humidity at a value (or range) desired by the user, thereby providing a more comfortable sleep environment.

[Brief description of the drawings]

FIG. 1 is a schematic perspective view of a room in which an air conditioner according to an embodiment of the present invention is installed.

FIG. 2 is a block diagram of the air-conditioning apparatus according to Embodiment 1.

FIG. 3 is a flowchart of air conditioning control according to the first embodiment.

FIG. 4 is a diagram schematically illustrating a room where an air conditioner according to a second embodiment is installed.

FIG. 5 is a diagram showing a relationship between an environmental temperature and a heat radiation amount from a human body.

FIG. 6 is a flowchart of air conditioning control according to the second embodiment.

FIG. 7 is a block diagram of an air conditioner according to Embodiment 3.

FIG. 8 is a flowchart of air conditioning control according to the third embodiment.

FIG. 9 is a block diagram of an air conditioner according to Embodiment 4.

FIG. 10 is a flowchart of air conditioning control according to the fifth embodiment.

FIG. 11 is a diagram showing changes over time in a room temperature, a room humidity, and a body heat equilibrium state in a fifth embodiment.

FIG. 12 is a diagram showing the relationship between sleep time and the amount of perspiration.

FIG. 13 is a flowchart of air conditioning control according to the sixth embodiment.

FIG. 14 is a diagram schematically illustrating a room in which an air conditioner according to a seventh embodiment is installed.

FIG. 15 is a flowchart of air conditioning control according to the seventh embodiment.

FIG. 16 is a diagram showing a change over time in a room temperature, a room humidity, and a body heat equilibrium state according to a conventional technique.

FIG. 17 is a diagram showing a temporal change in a room temperature, a room humidity, and a body heat equilibrium state according to a conventional technique.

[Explanation of symbols]

 (1) Air conditioner (2) Sleeper (5,6) Blood flow sensor (11) Air conditioner body (air conditioner body) (12) Temperature sensor (temperature detecting means) (13) Humidity sensor (humidity detecting means) (14) Heat balance calculation unit (calculation means) (15) Control unit (control means) (16) Heat balance storage unit (storage means) (17) Input unit (target value input means) (18) Sweating sensor (Sweating amount detection means)

Claims (16)

[Claims] 1. An air conditioner body (11) for performing at least heating or cooling of room air and humidification or dehumidification of room air, a temperature detecting means (12) for detecting room temperature, and detecting room humidity. Humidity detecting means (13), based on the detected temperature of the temperature detecting means (12) and the detected humidity of the humidity detecting means (13), the air conditioning apparatus body ( Control means for controlling 11)
(15) An air conditioner comprising: 2. An air conditioner main body (11) for performing at least heating or cooling of indoor air and humidification or dehumidification of indoor air; a temperature detecting means (12) for detecting indoor temperature; and detecting indoor humidity. Humidity detecting means (13), and calculating means (14) for calculating the heat balance of the human body of the sleeping person (2) based on the detected temperature of the temperature detecting means (12) and the detected humidity of the humidity detecting means (13). ), And control means (15) for controlling the air conditioner body (11) so that the heat balance becomes a predetermined value. 3. An air conditioner main body (11) for performing at least heating or cooling of room air and humidification or dehumidification of room air, and a physiological amount detecting means (5, 5) for detecting a physiological amount of a sleeping person (2). 6), calculating means (14) for calculating the heat balance of the human body of the sleeping person (2) based on the physiological amount, and the air conditioner main body (11) so that the heat balance becomes a predetermined value. An air conditioner characterized by comprising control means (15) for controlling air conditioning. 4. The air conditioner according to claim 3, wherein the physiological amount detecting means includes a blood flow sensor (5, 6). 5. The air conditioner according to claim 1, wherein the control means (15) controls the air conditioner body (11) such that the heat balance becomes zero. An air conditioner characterized by being configured to perform the following. 6. An air conditioner body (11) for performing at least heating or cooling of room air and humidification or dehumidification of room air, a temperature detecting means (12) for detecting room temperature, and detecting room humidity. Humidity detecting means (13), based on the detected temperature of the temperature detecting means (12) and the detected humidity of the humidity detecting means (13), the heat balance Q and wet area ratio ω of the human body of the sleeping person (2). Calculation means (14), and control means (15) for controlling the air conditioner main body (11) such that the heat balance amount Q and the wetted area ratio ω become predetermined values, respectively. An air conditioner characterized by the following. 7. The air conditioner according to claim 6, wherein the control means (15) includes a heat balance amount Q = 0 and a wet area ratio ω =
An air conditioner characterized by controlling the air conditioner body (11) to be 0.06. 8. An air conditioner main body (11) for performing at least heating or cooling of room air and humidification or dehumidification of room air, a temperature detecting means (12) for detecting room temperature, and detecting room humidity. Humidity detecting means (13), and calculating means (14) for calculating the heat balance of the human body of the sleeping person (2) based on the detected temperature of the temperature detecting means (12) and the detected humidity of the humidity detecting means (13). Storage means for storing the heat balance of the sleeping person (2) before falling asleep
(16), and control means (15) for controlling the air conditioner body (11) such that the heat balance of the sleeping person (2) after falling asleep is equal to the heat balance before falling asleep. An air conditioner, comprising: 9. An air conditioner main body (11) for performing at least heating or cooling of room air and humidification or dehumidification of room air, a temperature detecting means (12) for detecting room temperature, and detecting room humidity. Humidity detecting means (13), and calculating means (14) for calculating the heat balance of the human body of the sleeping person (2) based on the detected temperature of the temperature detecting means (12) and the detected humidity of the humidity detecting means (13). ), Target value input means (17) for externally inputting a target value of the heat balance amount, and control means (17) for controlling the air conditioner body (11) so that the heat balance amount becomes the target value. 15) An air conditioner comprising: 10. The air conditioner according to claim 1, wherein the temperature detecting means (12) is configured to detect a temperature in the bed instead of the room temperature. The air conditioner, wherein the humidity detecting means (13) is configured to detect humidity in the bed instead of indoor humidity. 11. The air conditioner according to claim 1, wherein the control means (15) has a relative humidity of 40 for a predetermined time after the sleeping person (2) falls asleep. An air conditioner that performs control to lower the indoor humidity within a range not less than 10% before falling asleep. 12. The air conditioner according to claim 11, wherein the control means (15) controls the indoor humidity to decrease after the sleeping person (2) falls asleep, and then to gradually increase the indoor humidity. An air conditioner characterized by performing. 13. The air conditioner according to claim 1, further comprising: a sweating amount detecting means (18) for detecting a sweating amount of the sleeping person (2), wherein the control means (15) An air conditioner characterized by performing control for adjusting the indoor humidity according to the amount of perspiration. 14. The air conditioner according to any one of claims 1 to 13, wherein the air conditioner main body (11) is configured to be able to freely change one or both of the amount and direction of the blown air. The control means (15) adjusts one or both of the air volume and the air direction of the air blown out of the air conditioner main body (11) so that the heat balance of the human body of the sleeping person (2) becomes a predetermined value. An air conditioner characterized by performing. 15. The air conditioner according to any one of claims 1 to 14, wherein the air conditioner main body (11) is configured to be able to change the temperature of the blown air, and the control means (15) comprises: An air conditioner wherein the temperature of the air blown from the air conditioner main body (11) is adjusted so that the heat balance of the human body of the sleeping person (2) becomes a predetermined value. 16. The air conditioner according to claim 1, further comprising: target value input means for externally inputting a target value of the room temperature or the indoor humidity, and a control means (15). Controlling the air conditioner body (11) such that the indoor temperature or indoor humidity becomes the target value and the heat balance of the human body of the sleeping person (2) becomes a predetermined value. .