JP2000186840A - Air conditioning device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform optimum control of room air quality so as to match with a life scene. SOLUTION: An air conditioner comprises an inputting device 1 through which at least a bedtime and a get-up time can be inputted, CO2 sensor 2 for detecting CO2 concentration of a room, a ventilating device 4 for ventilating indoor and outdoor air, and a control unit 3 for operating the ventilating device 4 in accordance with the times inputted through the inputting device and a CO2 sensor output. The control unit 3 forcibly operates the ventilating device before a first given period of time lapses from the get-up time, and after lapse of the first given period of time, operates the ventilating device according to the CO2 sensor output at not less than a first CO2 concentration. From the bedtime to the get-up time, the ventilating device is operated at not less than a second CO2 concentration which is higher than the first CO2 concentration. Thus, ventilating operation which matches with a life scene derived from the get-up time and bedtime can be achieved.

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 that performs optimal control of air quality to obtain a comfortable sleep and a refreshing awakening in consideration of use in a bedroom. .

[0002]

2. Description of the Related Art An air conditioner related to air quality is used to reduce CO ₂
As for automatic operation in accordance with the CO ₂ concentration by the sensor, there is one disclosed in JP-A-3-102126. This is to activate the ventilation fan when the output of the CO ₂ sensor reaches or exceeds a predetermined level. Japanese Patent Application Laid-Open No. 6-281219 discloses that similar control is performed using a miscellaneous gas sensor. Further, Japanese Patent Application Laid-Open No. 9-89317 discloses an apparatus in which a ventilator is operated based on the CO ₂ concentration and, in conjunction with the ventilator, emits and deodorizes Fittin Cid.

[0003]

In the above-mentioned air conditioner, the indoor CO ₂ concentration can be maintained at a certain value or less, and energy is saved because ventilation is not performed more than necessary. However, the air conditioner merely secures a certain level of air quality, and is not controlled according to the life scene.

That is, FIG. 3 shows the daily fluctuation of the indoor CO ₂ concentration when two persons are present in a 6-tatami room without a ventilation device, and reaches 3000 ppm at dawn. In addition, it can be seen from the increase in the indoor CO ₂ concentration that the person is in the room other than at bedtime. In general, indoor CO ₂ concentration is said to be an index of air pollution, and 1000 pp in building environmental standards.
m. On the other hand, the CO ₂ concentration affects the human body at a high concentration, although respiratory disorders occur at a high concentration, but even at a low concentration, there is an effect such as a decrease in work efficiency and sleepiness.

[0005] The present invention has been made in view of the above points, and the object thereof is to achieve an energy-saving effect and perform control in accordance with a life scene to obtain particularly comfortable sleep and refreshing awakening. It is an object of the present invention to provide an air conditioner capable of performing optimal control of indoor air quality as described above.

[0006]

Means for Solving the Problems] Thus the air conditioning apparatus according to the present invention comprises an input device capable of inputting at least bedtime, rising time, and CO ₂ sensor for detecting the indoor CO ₂ concentration, the indoor and outdoor air A ventilation device to be replaced, and a control device that activates the ventilation device according to the time input by the input device and the output of the CO ₂ sensor, and the control device is configured to operate the ventilation device until the first predetermined time elapses from the wake-up time. The ventilation device is forcibly operated, and after the first predetermined time has elapsed, the C
The ventilator is operated at the first CO ₂ concentration or higher by the output of the O ₂ sensor, and the ventilator is operated at the second CO ₂ concentration higher than the first CO ₂ concentration during the period from bedtime to wake-up time. The feature is that it is made to be.

[0007] A ventilation operation according to a life scene obtained from a wake-up time or a bedtime is obtained.

[0008] The forced operation of the ventilator at the time of wake-up by the control device may be performed from a time point a second predetermined time before the wake-up time. Furthermore, CO is the CO ₂ concentration obtained from the _second sensor may be one which takes place only when exceeding the first CO ₂ concentration.

The control device is provided with a negative ion generator, the control device operates the negative ion generator from bedtime to the wake-up time, and the fitted device is provided. At the same time, it is also preferable to operate the fitted-in generator.

The control device further includes a data storage unit for storing weekly, monthly, and yearly pattern data based on the bedtime and wake-up time input by the input device, and the bedtime and wake-up time are input. If not, the control operation may be performed based on the bedtime and wakeup time predicted by the pattern data.

It is preferable that the ventilation device has a heat exchange ventilation function.

[0012] Further, it is provided with a dust sensor and an air cleaning device, and an air cleaning device that operates when the amount of dust obtained by the dust sensor is equal to or more than a predetermined value is also provided for the outside air introduced by the ventilation device. It is also preferable that a purifying function be performed.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail based on an example of an embodiment. As shown in FIG. 1, an air conditioner according to the present invention includes a ventilation device 4 and an operation of the ventilation device 4. In addition to the control device 3 for controlling, an input device 1 capable of inputting bedtime and wake-up time together with normal input is provided. It can be operated from. Further, the control device 3 is connected to the CO ₂ sensor 2, the storage device 7, the fitted-tin generator 5, and the negative ion generator 6. The CO ₂ sensor 2 detects the CO ₂ concentration in the room.

The control device 3 optimally controls the ventilation device 4, the fitted-tin generator 5, and the negative ion generator 6 based on information from the input device 1 and the CO ₂ sensor 2, and inputs data from the input device 1. The obtained bedtime and wake-up time are processed as weekly, monthly and yearly pattern data and stored in the storage device 7.

The ventilator 4 discharges dirty air indoors to the outside and introduces fresh outside air. At this time, pollutants such as dust and NOx contained in the outside air are absorbed and purified by a filter. The outside air purified by the above is introduced. Further, a heat exchange type is used to prevent heat loss due to ventilation during indoor heating or cooling.

The fittin cide generator 5 generates a proper amount of fittin cide, which is a volatile plant essential oil collected from a tree or the like. Here, Fittin Cide has a deodorizing / sterilizing effect and can obtain a forest bathing effect.

The negative ion generator 6 generates negative ions by a discharge method using a discharge needle to which a high voltage is applied, or a water crushing method using the Leonard effect. Negative ions have a relaxing effect and a recovery effect under stress.

Next, the control operation will be described. The control device 3 divides a day into three time zones A, B, and C according to the wake-up time M and the bedtime S input from the input device 1.
The ventilator 4, the fitted-tin generator 5 and the negative ion generator 6 are operated in accordance with the time zones A, B and C.

That is, in the time zone A between the time when the first predetermined time t1 has elapsed from the wake-up time M and the bedtime S, the ventilator 4 according to the CO ₂ concentration in the room obtained from the CO ₂ sensor. To work. If more than the first CO ₂ concentration (e.g. 1000 ppm), the indoor CO ₂ concentration by the introduction of outside air by operating the ventilator 4 a first CO ₂
Keep below the concentration.

[0020] Next, at time zone B from bedtime S to a second predetermined time before t2 of wake time M is the indoor obtained by CO ₂ sensor CO ₂ concentration is high second than the first CO ₂ concentration C
When O ₂ concentration (for example, 3000 ppm) or more,
The ventilation device 4 is operated.

Then, during the time zone C between the time zone B and the time zone A, that is, the time point a second predetermined time t2 before the wake-up time M and until the first predetermined time t1 elapses, a forced operation is performed. The ventilation device 4 is operated.

In the area of the time zone A, which is a time zone of human activity, the CO ₂ concentration is kept at the first CO ₂ concentration or less, and a state suitable for activities such as work and study is secured. .

In the time zone B, which is a bedtime, the operation of the ventilator 4 is suppressed, the noise can be reduced, and the CO ₂ concentration is increased to some extent, so that it is easier to fall asleep. Can be

Next, in the time zone C before and after the wake-up time M, the CO ₂ concentration is reduced to the outside air level by the forced ventilation, and a refreshing awakening is obtained.

Further, in time zone B, which is a bedtime, the negative ion generator 6 is operated to generate negative ions (for example, 5000 ions / cc). By generating negative ions, a relaxing effect can be obtained and it is easy to fall asleep, and a stress recovery effect can be obtained during bedtime, so that a comfortable sleep can be achieved.

Further, in the time zone C before and after the wake-up time M, the fitted-in generator 5 is operated to deodorize
By generating an appropriate amount of Fittin Cid that has a bactericidal effect, freshness can be obtained and a forest bathing effect can be expected.
The effect of comfortable awakening increases. At this time, if the generation amount of the fittin is gradually increased, it is possible to expect that there is less discomfort than in the case where an appropriate amount is generated from the beginning and that the comfort is increased.

When the ventilator 4 is operated in accordance with the CO ₂ concentration, the first and second CO ₂ concentrations are given a hysteresis so that the on / off operation is not frequently repeated, or the CO ₂ concentration is reduced. Of course, it is preferable to change the operation level of the ventilator 4 according to it.

If the bedtime and wake-up time are not input on that day, the control device 3 estimates the bedtime and wake-up time from the pattern data in the storage device 7, and performs the control operation based on the estimated time. Therefore, an almost accurate operation can be obtained.

In a time zone C before and after the wake-up time M, C
The ventilation device 4 may be forcibly operated only when the indoor CO ₂ concentration obtained by the O ₂ sensor exceeds the first CO ₂ concentration. Similarly, the fitted-in generator 5 may not be operated. By doing so, unnecessary operations when the CO ₂ concentration does not increase, such as when the user is absent, can be omitted.

FIG. 2 shows another example. This is added with a dust sensor 8 for detecting the dust concentration in the room and an air purifier 9 for taking in the air in the room and purifying the dust with an electric dust collector or a filter. It is preferable that the apparatus can purify air with respect to the outside air introduced in No. 3.

In this embodiment, the control device 3 controls the air cleaning device 9 according to the dust concentration detected by the dust sensor 8.
Is operated to purify the indoor air quality. At this time,
Similarly to the control of the ventilation device 4, the operation level of the air cleaning device 9 may be changed according to the time zones A, B, and C. As a result, for dust that can be purified by a filter, etc.,
Instead of the substitute detection by the CO ₂ sensor 2, the dust can be directly detected by the dust sensor 8, and the processing can be performed by internal circulation without ventilation, so that more optimal air quality can be obtained and energy can be saved.

Further, in the present invention, since the wake-up time is input, it is naturally possible to easily add a wake-up function.

[0033]

As described above, in the present invention, the driving mode is switched from the input wake-up time or bedtime, and the air quality can be optimally controlled according to the life scene. Exhilarating awakening can be expected, and energy can be saved.

A more comfortable wake-up can be obtained if the forced operation of the ventilator by the control device at the time of wake-up is performed from a time point a second predetermined time before the wake-up time.

Further, the forced operation of the ventilator at the time of getting up is set to CO.
Is CO ₂ concentration obtained from ₂ sensor when only causes when exceeding the first CO ₂ concentration can be achieved in order to be able to avoid the forced operation of Office, more energy saving.

The control device is provided with a negative ion generator, the control device is operated from the bedtime to the wake-up time, the fitted ion generator is provided, and the control device is a forced operation of the ventilation device. At the same time, a more comfortable air quality can be obtained by operating the fitted-in generator.

The control device further includes a data storage unit for storing weekly, monthly and yearly pattern data based on the bedtime and wake-up time inputted by the input device, and the bedtime and wake-up time are inputted. When there is no such time, if the control operation is performed based on the bedtime and the wakeup time predicted by the pattern data, an appropriate operation can be obtained even if the user forgets to input the bedtime or the wakeup time.

It is preferable that the ventilator has a heat exchange ventilation function from the viewpoint of energy saving.

Further, the apparatus is provided with a dust sensor and an air purifying device. The air purifying device, which operates when the amount of dust obtained by the dust sensor is equal to or more than a predetermined value, is also provided for the outside air introduced by the ventilation device. If the purifying function is used, more comfortable air quality can be reliably obtained.

[Brief description of the drawings]

FIG. 1 shows an example of an embodiment of the present invention, in which (a)
Is a block diagram, and (b) is an operation time chart.

FIG. 2 is a block diagram of another example.

FIG. 3 is an explanatory diagram showing the daily fluctuation of the indoor CO ₂ concentration.

[Explanation of symbols]

1 input device 2 CO ₂ sensor 3 control unit 4 ventilators 5 Fitton nitride de generator 6 negative ion generating device 7 memory

Claims (8)

[Claims] 1. A least an input device capable of inputting a bedtime-wake-up time, the indoor CO ₂ and CO ₂ sensor for detecting the concentration, the ventilator replacing the indoor and outdoor air, time and CO ₂ that is input by the input device A control device for operating the ventilation device according to the sensor output, wherein the control device forcibly operates the ventilation device until a first predetermined time elapses from the wake-up time, and after the first predetermined time elapses, The CO ₂
The ventilator is operated at the first CO ₂ concentration or higher by the sensor output, and the first C is supplied from the bedtime to the wake-up time.
The air conditioner, wherein the ventilator is operated at a second CO ₂ concentration higher than the O ₂ concentration or higher. 2. The air conditioner according to claim 1, wherein the control device starts the forced operation of the ventilator from a time point a second predetermined time before the wake-up time. 3. The control device controls the forced operation of the ventilator by CO.
₂ air conditioning apparatus of claim 1 or 2, wherein the CO ₂ concentration obtained from the sensor is one which only performed when exceeding a first CO ₂ concentration. 4. A negative ion generator is provided,
The air conditioner according to any one of claims 1 to 3, wherein the control device activates the negative ion generator from a bedtime to a wake-up time. 5. A fitting device according to claim 1, further comprising a fitting device, wherein the control device activates the fitting device simultaneously with the forced operation of the ventilation device. The air conditioner according to any of the above items. 6. The control device includes a data storage unit that stores weekly, monthly, and yearly pattern data based on the bedtime and wake-up time input by the input device.
The air conditioning according to any one of claims 1 to 5, wherein a control operation is performed based on a bedtime and a wake-up time predicted by the pattern data when the wake-up time is not input. apparatus. 7. The air conditioner according to claim 1, wherein the ventilation device has a heat exchange ventilation function. 8. An air purifying device comprising a dust sensor and an air purifying device, wherein the air purifying device operates when the amount of dust obtained by the dust sensor is equal to or more than a predetermined value. 2. The air conditioner according to claim 1, wherein the air conditioner operates a purifying function.