JP2016217653A - Air conditioning control system, air conditioner, air conditioning method and air conditioning control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning control system, an air conditioning control device, an air conditioning control method and an air conditioning control program that can restrict in-taking of substances that should not be taken into a room.SOLUTION: An air conditioning control system of this preferred embodiment includes a first determination part, a second determination part and a decision part. The first determination part compares a temperature state and a humidity state of indoor air with a temperature state and a humidity state of outdoor air to determine whether or not the outside air is taken into a room. The second determination part determines whether or not the outdoor air is taken into a room on the basis of a state of contamination substance in indoor air and a state of contamination substance in outdoor air. The decision part determines whether or not the outdoor air is taken into a room on the basis of a result determined by the first determination part and a result determined by the second determination part.SELECTED DRAWING: Figure 2

Description

  Embodiments described herein relate generally to an air conditioning control system, an air conditioning control device, an air conditioning control method, and an air conditioning control program.

  2. Description of the Related Art Conventionally, an air conditioning control system that takes outdoor air into a room and adjusts the state of the room air is known. The air conditioning control system detects indoor and outdoor air conditions such as outdoor air temperature and humidity, indoor air temperature and humidity, and determines whether to take outdoor air into the room based on the detected indoor and outdoor air conditions. , And the amount of outdoor air intake was controlled. However, since the air-conditioning control system does not control the outdoor environment with sufficient consideration, there is a possibility that a substance that should not be taken into the room may be taken into the room.

JP 2012-159244 A JP 2008-25851 A

  The problem to be solved by the present invention is to provide an air conditioning control system, an air conditioning control device, an air conditioning control method, and an air conditioning control program that can suppress the introduction of substances that should not be taken into the room.

  The air conditioning control system of the embodiment includes a first inside air detection unit, a first outside air detection unit, a second inside air detection unit, a second outside air detection unit, a first determination unit, and a second It has a determination part and a determination part. The first room air detector detects the temperature and humidity state of the room air in the predetermined space. The first outside air detection unit detects the temperature and humidity state of the outdoor air outside the predetermined space. The second room air detector detects the state of pollutants in the room air. The second outside air detection unit detects the state of contaminants in the outdoor air. The first determination unit compares the temperature / humidity state detected by the first inside air detection unit with the temperature / humidity state detected by the first outside air detection unit, and takes in outdoor air into the predetermined space. Determine whether or not. The second determination unit takes outdoor air into the predetermined space based on the state of the contaminant detected by the second inside air detection unit and the state of the contaminant detected by the second outside air detection unit. It is determined whether or not. The determining unit determines whether or not to take outdoor air into the predetermined space based on the result determined by the first determining unit and the result determined by the second determining unit.

The block diagram which shows the structure of the air-conditioning control system 1 in 1st Embodiment. The block diagram which shows the functional structure of the air-conditioning control part 100 in 1st Embodiment. The flowchart which shows operation | movement of the air-conditioning control system 1 in 1st Embodiment. The flowchart which shows an example of the flow which takes in external air and controls the state of room air in 1st Embodiment. The block diagram which shows the structure of 100 A of air-conditioning control parts in 2nd Embodiment. 9 is a flowchart illustrating an example of a flow for notifying a decrease in the removal efficiency of contaminants in the second embodiment.

Hereinafter, an air conditioning control system, an air conditioning control device, an air conditioning control method, and an air conditioning control program according to embodiments will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a block diagram showing a configuration of an air conditioning control system 1 in the first embodiment. The air conditioning control system 1 controls the air state in a predetermined space. The predetermined space is a space in which the air condition is controlled by the air conditioning control system 1. The predetermined space is, for example, one indoor space in a house where the user lives.

  The air conditioning control system 1 includes an air conditioning control device 10. The air conditioning control device 10 includes an air conditioning control unit 100, an indoor air introduction port 102, and a conditioned air discharge port 104. In addition, the air conditioning control device 10 includes a temperature / humidity sensor 106 for room air and a pollutant sensor 108 for room air. The air conditioning control device 10 is connected to an outside air duct 110. The outdoor air duct 110 is connected to an outdoor air introduction port 112 through which outdoor air is introduced. The outdoor air duct 110 is provided with an outdoor air temperature / humidity sensor 114 and an outdoor air contaminant sensor 116.

  The air conditioning control unit 100 comprehensively controls each unit in the air conditioning control system 1. Thereby, the air-conditioning control part 100 controls the state of the air in a predetermined space. The air-conditioning control apparatus 10 can implement a function to be described later on a controller in, for example, a HEMS (Home Energy Management System) or a BEMS (Building Energy Management System). Each unit in the air conditioning control unit 100 is a software function unit that functions when a processor such as a CPU (Central Processing Unit) executes a program stored in a storage unit (not shown). The air conditioning control unit 100 may be a hardware function unit such as an LSI (Large Scale Integration) or an ASIC (Application Specific Integrated Circuit).

  Air (room air) in a predetermined space is introduced into the room air inlet 102. The temperature and humidity of the indoor air introduced into the indoor air inlet 102 are adjusted by an air conditioner such as a heat exchanger (not shown). The conditioned air whose temperature and humidity are adjusted by the air conditioning equipment is discharged from the conditioned air discharge port 104 to a predetermined space.

  The indoor air temperature / humidity sensor 106 detects the temperature value and the humidity value of the indoor air introduced into the indoor air inlet 102. The temperature value and humidity value of the room air are output to the air conditioning control unit 100 by the room air temperature / humidity sensor 106. Further, the indoor air introduced into the indoor air inlet 102 is detected by the indoor air contaminant sensor 108. The indoor air pollutant sensor 108 outputs a signal having a value corresponding to the concentration of the pollutant in the indoor air to the air conditioning control unit 100.

  The outdoor air introduction port 112 is connected to an outdoor unit (not shown) that exchanges heat by sucking air outside the predetermined space (outdoor air). The outdoor air introduced into the outdoor air introduction port 112 is supplied to the air conditioning control device 10 via the outdoor air duct 110. The outside air duct 110 is provided with a contaminant removal filter 110a that removes contaminants in the outdoor air. In addition, although the pollutant removal filter 110a showed an example provided in the duct 110 for external air, you may provide in other places into which outdoor air, such as the outdoor air inlet 112, is introduce | transduced. The outdoor air taken in by the air conditioning control device 10 is adjusted in temperature and humidity by air conditioning equipment such as a heat exchanger (not shown). The conditioned air whose temperature and humidity are adjusted by the air conditioning equipment is discharged from the conditioned air discharge port 104 to a predetermined space.

  For example, the outdoor air temperature / humidity sensor 114 detects the temperature value and the humidity value of the outdoor air introduced into the outdoor air duct 110. In the present embodiment, an example of detecting the temperature value and the humidity value of the outdoor air introduced into the outdoor air duct 110 has been shown, but many outdoor air temperature / humidity sensors are generally employed. It may be installed outside such a building, and the temperature value and humidity value of outdoor air may be detected. The temperature value and humidity value of the outdoor air are output to the air conditioning control unit 100 by the outdoor air temperature / humidity sensor 114. Further, the outdoor air introduced into the outdoor air duct 110 is detected by the outdoor air contaminant sensor 116. The outdoor air pollutant sensor 116 outputs a signal having a value corresponding to the concentration of the pollutant in the outdoor air to the air conditioning control unit 100.

  In addition, in embodiment, although demonstrated as a thing provided with the sensor which detects the state of outdoor air, the state of outdoor air is acquired by the air-conditioning control apparatus 10 via a network, and is output to the air-conditioning control part 100. Also good.

FIG. 2 is a block diagram illustrating a functional configuration of the air conditioning control unit 100 according to the first embodiment.
The air conditioning control unit 100 includes a first signal input unit 120, an outside air intake condition calculation unit 122, a second signal input unit 124, an environmental state determination unit 126, an outside air intake determination unit 128, and a control output unit 130. With.

  The first signal input unit 120 is connected to the indoor air temperature / humidity sensor 106 and the outdoor air temperature / humidity sensor 114. The first signal input unit 120 detects a temperature / humidity state included in the room air (a first room air detection unit). Moreover, the 1st signal input part 120 detects the temperature / humidity state contained in outdoor air (1st outdoor air detection part). The first signal input unit 120 inputs the temperature value and humidity value of the indoor air and the temperature value and humidity value of the outdoor air, and supplies them to the outdoor air intake condition calculation unit 122.

  The outdoor air intake condition calculation unit 122 compares the temperature / humidity state of the indoor air with the temperature / humidity state of the outdoor air, and determines whether or not the outdoor air is taken into the predetermined space (first determination unit). The result determined by the outside air intake condition calculation unit 122 is a condition (outside air intake condition) for determining whether to take in outdoor air.

In the embodiment, the outdoor air intake condition calculation unit 122 calculates the enthalpy using the temperature and humidity state of the indoor air and the temperature and humidity state of the outdoor air. Enthalpy is calculated according to Equation 1 below.
h = Ca * t + x (Cv * t + r0) (Formula 1)
In the above formula 1, h is enthalpy and is represented by J / kg [kcal / kg]. Moreover, Ca is the constant pressure specific heat of dry air, and is expressed as 1005 J / Kg · K and 0.240 [kcal / kg · ° C.]. Cv is the constant-pressure specific heat of water vapor, and is expressed as 1846 [J / kg · K] and 0.441 [kcal / kg · ° C.]. r0 is the latent heat of vaporization of water at 0 ° C., and is expressed as 2501 × 103 [J / kg] and 597.5 [kcal / kg]. t is the dry bulb temperature (air temperature) [° C.]. x is absolute humidity [kg / kg].

The absolute humidity x is calculated using the water vapor partial pressure Pw according to the following equation 2.
x = 0.602198 × Pw / (101.325-Pw) (Formula 2)
In the above formula 2, the water vapor partial pressure Pw is calculated by the following formula 4 obtained by modifying the following formula 3 using the relative humidity Ψ [%] and the saturated water vapor partial pressure Pws [kPa (mmHg)].
Ψ = Pw / Pws × 100 (Formula 3)
Pw = (Ψ × Pws) / 100 (Formula 4)
Pws in the above equation 4 is
Pws = [exp {−5800.2206 / T + 1.3914993−0.0486640239 × T + 0.417664768 × 10 ⁻⁴ × T ² −0.14452093 × 10 ⁻⁷ × T ³ + 6.549673 × log _e (T)}] / 1000 (Formula 5)
It is expressed. In the above formula 5, T is the absolute temperature [K], and T is the dry bulb temperature t + 273.15.

  The outside air intake condition calculation unit 122 converts the temperature value of the room air input by the first signal input unit 120 into the dry bulb temperature t for obtaining the dry bulb temperature t in the above equation 1 and the absolute temperature T in the above equation 5. Substituting the humidity value of the room air input by the first signal input unit 120 into the relative humidity x in the above equation 1 and the relative humidity ψ in the above equation 4. Thereby, the outside air intake condition calculation unit 122 calculates the indoor enthalpy as the state of the indoor air. Further, the outside air intake condition calculation unit 122 uses the temperature value of the outdoor air input by the first signal input unit 120 as the dry bulb temperature for obtaining the dry bulb temperature t in Equation 1 and the absolute temperature K in Equation 5 above. Substituting into t, the humidity value of the outdoor air input by the first signal input unit 120 is substituted into the relative humidity x in Equation 1 and the relative humidity ψ in Equation 4. Thereby, the outside air intake condition calculation unit 122 calculates the outdoor enthalpy as the state of the outdoor air.

  The 2nd signal input part 124 detects the state of the pollutant of indoor air (2nd inside air detection part). The second signal input unit 124 detects the state of contaminants in the outdoor air (second outdoor air detection unit). The second signal input unit 124 is connected to the indoor air contaminant sensor 108 and the outdoor air contaminant sensor 116. The second signal input unit 124 inputs a signal value representing the state of pollutants in the indoor air and a signal value representing the state of pollutants in the outdoor air, and supplies them to the environmental state determination unit 126.

  The second signal input unit 124 inputs, for example, the concentration of the contaminant as the state of the contaminant. A pollutant is a substance that adversely affects the human body when taken into the body. Contaminants include, for example, sulfur oxide (SOx) generated when fossil fuel burns, nitrogen oxide (NOx) generated by burning fuel, and photochemical oxidant (Ox) generated when nitrogen oxide causes a photochemical reaction. ), Particulate matter (PM) such as vehicle exhaust gas and dust, suspended particulate matter (SPM) having a particle size below a predetermined value among particulate matter, and finer particulate matter having a smaller particle size such as PM2.5 It is a substance. The pollutant may be a chemical substance generated indoors. Examples of chemical substances generated indoors include volatile organic compounds produced from building materials or furniture preservatives, and organic solvents such as formaldehyde contained in adhesives or paints. In the embodiment, an example in which the second signal input unit 124 inputs the concentration of the pollutant peculiar to the outdoor air unless the pollutant peculiar to the outdoor air and the pollutant peculiar to the indoor air will be described separately. Will be described.

  Based on the detection result by the indoor air pollutant sensor 108 and the detection result by the outdoor air pollutant sensor 116, the environmental state determination unit 126 determines whether or not outdoor air is taken into the predetermined space (second determination). Part). The environmental state determination unit 126 determines an environmental state related to the pollutant by taking outdoor air into the predetermined space by the determination process. The environmental state determination unit 126 supplies the determination result to the outside air intake determination unit 128.

  The outside air intake determination unit 128 determines whether to take outdoor air into the predetermined space based on the result determined by the outside air intake condition calculation unit 122 and the result determined by the environmental state determination unit 126 (decision). Part). The outside air intake determination unit 128 determines that either the result determined by the outside air intake condition calculation unit 122 or the result determined by the environment state determination unit 126 does not take outdoor air into the predetermined space. Determines not to take outdoor air into the predetermined space. The outdoor air intake determination unit 128 determines that both the result determined by the outdoor air intake condition calculation unit 122 and the result determined by the environmental state determination unit 126 are determined to take outdoor air into the predetermined space. The outdoor air is determined to be taken into the predetermined space. The control output unit 130 performs control for taking in outdoor air via the outdoor air introduction port 112 when the outdoor air intake determining unit 128 determines to take outdoor air into the predetermined space. The control output unit 130 drives, for example, an intake fan (not shown) provided in the outdoor air inlet 112 to take outdoor air into the outdoor air inlet 112 and the outdoor air duct 110. The control output unit 130 does not perform control for taking in outdoor air when the outdoor air intake determining unit 128 determines not to take outdoor air into the predetermined space.

Hereinafter, the operation of the air conditioning control system 1 in the first embodiment will be described.
FIG. 3 is a flowchart showing the operation of the air conditioning control system 1 in the first embodiment. The air conditioning control unit 100 determines whether or not the control start condition is satisfied every predetermined time when the air conditioning control unit 100 is activated (step S100). The air conditioning control unit 100 repeats the determination in step S100 when the control start condition is not satisfied. When the control start condition is satisfied, the air conditioning control unit 100 performs an operation for controlling the state of the room air (step S102). The air conditioning control unit 100 determines whether or not the control continuation condition is satisfied for each predetermined period when controlling the state of the room air (step S104). The air conditioning control unit 100 continues the control of the indoor air state when the control continuation condition is satisfied. If the control continuation condition is not satisfied, the air conditioning control unit 100 determines whether or not the control end condition is satisfied (step S106). The air-conditioning control unit 100 ends the processing when the activation state of the air-conditioning control device 10 of the air-conditioning control device 10 is off and does not satisfy the operation continuation condition, and ends the process, and satisfies the control termination condition If not, the process returns to step S100.

FIG. 4 is a flowchart illustrating an example of a flow for controlling the state of room air in the first embodiment. The following description corresponds to the operations in steps S100 and S104 described above.
The air conditioning control unit 100 determines whether or not the air conditioning control device 10 satisfies the operating condition (step S110). The air conditioning control unit 100 determines, as operation conditions, whether the activation state of the air conditioning control device 10 is on and whether the operation mode of the air conditioning control device 10 is cooling. If it is determined that the activation state of the air conditioning control device 10 is on and the operation mode of the air conditioning control device 10 is cooling, the air conditioning control unit 100 advances the process to step S112. The air-conditioning control unit 100 stops the operation of the air-conditioning control device 10 when the activation state of the air-conditioning control device 10 is on and the operation condition of the air-conditioning control device 10 is cooling is not satisfied. Then, the process ends (step S124).

  The air conditioning control unit 100 inputs the sensor signals detected by the temperature / humidity sensor 106 for indoor air and the temperature / humidity sensor 114 for outdoor air by the first signal input unit 120, and the room air by the second signal input unit 124. Sensor signals detected by the indoor pollutant sensor 108 and the outdoor air pollutant sensor 116 are input (step S112).

  The air conditioning control unit 100 determines whether or not the temperature and humidity condition is satisfied based on the sensor signal detected in step S112 by the outside air intake determination unit 128 (step S114). The temperature and humidity conditions are conditions of temperature and humidity at which outdoor air is taken in by the air conditioning control device 10 and the state of the indoor air can be controlled. The temperature and humidity conditions are, for example, that the temperature of the outdoor air is higher than a predetermined outdoor air cooling minimum temperature, the temperature of the indoor air is lower than the upper limit temperature of the indoor air, and the relative humidity of the indoor air is the humidity of the indoor air Three conditions of lower than the upper limit value are included. The minimum temperature at which outdoor air can be cooled and the humidity upper limit value of indoor air are values set in advance in the outdoor air intake determination unit 128. When the outside air intake determination unit 128 determines that all three conditions among the temperature and humidity conditions are satisfied, the process proceeds to step S116 and when it is determined that any one of the three conditions is not satisfied. Stops the operation and ends the processing (step S124).

  The outdoor air intake condition calculation unit 122 calculates the enthalpy of indoor air and the outdoor air based on the sensor signal detected in step S112 (step S116). The outside air intake determination unit 128 determines whether the enthalpy of room air (room E) is higher than a value obtained by adding a predetermined enthalpy difference α to the enthalpy of room air (outside air E). The predetermined enthalpy difference α is a difference between the enthalpy of the room air and the enthalpy of the room air set in order to start control of the state of the room air in step S100. Alternatively, the predetermined enthalpy difference α is a difference between the enthalpy of the room air and the enthalpy of the room air set in step S104 to continue the control of the state of the room air. The difference α of the enthalpy of the room air with respect to the enthalpy of the outdoor air set for starting or continuing the control of the state of the room air is a preset value. When the enthalpy of the room air is higher than the value obtained by adding the predetermined enthalpy difference α to the enthalpy of the outdoor air, the outside air intake determination unit 128 advances the process to step S118. If the enthalpy of the room air is not higher than the value obtained by adding the predetermined enthalpy difference α to the enthalpy of the outdoor air, the outside air intake determination unit 128 stops the operation and ends the process (step S124).

  Based on the sensor signal detected in step S112, the outdoor air intake determination unit 128 determines whether or not the concentration of contaminants in the outdoor air and indoor air is lower than a predetermined threshold (step S120). Two predetermined threshold values are set: a first threshold value that is compared with the concentration of the pollutant in the outdoor air, and a second threshold value that is compared with the concentration of the pollutant in the indoor air. The first threshold value and the second threshold value are values that suppress the influence on the human body when outdoor air is taken into the predetermined space. The first threshold value and the second threshold value may be preset values or values calculated based on a parameter including the concentration of the contaminant.

  When the concentration of contaminants in the outdoor air is lower than the first threshold value and the concentration of contaminants in the indoor air is lower than the second threshold value, the outdoor air intake determination unit 128 takes in outdoor air and An operation for controlling the air state is executed (started or continued) (step S122). The outdoor air intake determination unit 128 takes the outdoor air into the air conditioning control device 10 through the outdoor air inlet 112 by the control output unit 130 and controls the state of the indoor air with the conditioned air. When the outdoor air intake determination unit 128 does not satisfy one of the two conditions that the concentration of the contaminant in the outdoor air is lower than the first threshold and the concentration of the contaminant in the indoor air is lower than the second threshold. In step S124, the operation is stopped and the process is terminated.

  As described above, the air-conditioning control apparatus 10 can perform the determination in step S100 by setting the predetermined enthalpy difference α as the enthalpy difference for starting control in step S118. That is, the air-conditioning control apparatus 10 can start control of room air in step S102 by executing control of room air in step S122. Moreover, the air-conditioning control apparatus 10 can perform the determination in step S104 by setting the predetermined enthalpy difference α as the enthalpy difference for continuing control in step S118. That is, the air conditioning control device 10 can continue the control of the room air in step S102 by executing the control of the room air in step S122. Furthermore, the air-conditioning control apparatus 10 can execute the determination in step S106 by setting the predetermined enthalpy difference α in step S118 as the enthalpy difference for continuing control and stopping the operation in step S124. .

  As described above, the air-conditioning control apparatus 10 is higher in the enthalpy of the indoor air than the value obtained by adding the enthalpy difference for starting control to the enthalpy of the outdoor air, and the concentration of the pollutant in the outdoor air is predetermined. When it is lower than the threshold value, it is determined that the condition for starting control or continuing control is satisfied, and the state of indoor air can be controlled by taking in outdoor air. Therefore, according to the air-conditioning control device 10, it is possible to suppress the introduction of substances that should not be taken into the room.

  In the above-described embodiment, it is possible to suppress the introduction of contaminants peculiar to outdoor air into the predetermined space. However, when there is a pollutant peculiar to the indoor air generated in the predetermined space, the air conditioning control device 10 determines the concentration of the pollutant in the outdoor air and the concentration of the pollutant in the indoor air by the environmental state determination unit 126. In comparison, it may be determined whether outdoor air is taken into the predetermined space. For example, the environmental state determination unit 126 determines the outdoor air when the concentration of the pollutant peculiar to the indoor air is higher than a predetermined threshold (third predetermined value) even if the contaminant exists in the outdoor air. You may determine with taking in in predetermined space.

(Second Embodiment)
Hereinafter, the second embodiment will be described. FIG. 5 is a block diagram illustrating a configuration of an air conditioning control unit 100A according to the second embodiment. The air conditioning control unit 100A according to the second embodiment includes an indoor concentration calculation unit 140, a removal efficiency determination unit 142, and a state notification unit 144 with respect to the air conditioning control unit 100 according to the first embodiment illustrated in FIG. Prepare.

  The indoor concentration calculation unit 140 samples the concentration of the pollutant in the indoor air and the concentration of the pollutant in the outdoor air input by the second signal input unit 124 at predetermined intervals. The predetermined interval is set to a time during which the air conditioning control device 10 monitors the concentration of contaminants in the indoor air. The predetermined interval is, for example, 1 minute.

  The indoor concentration calculation unit 140 calculates the concentration of the pollutant in the outdoor air based on the concentration of the pollutant detected at the first timing and the pollutant concentration detected at the second timing. Calculate the amount of increase and the amount of increase in the concentration of pollutants in the room air. The indoor concentration calculation unit 140 calculates an average increase amount at a constant interval such as a predetermined interval for sampling, for example.

  The removal efficiency determination unit 142 calculates the contaminant removal efficiency in the contaminant removal filter 110a based on the increase amount of the contaminant concentration in the outdoor air and the increase amount of the contaminant concentration in the indoor air. For example, the removal efficiency determination unit 142 performs a calculation such that the contaminant removal efficiency in the contaminant removal filter 110a is lowered when the concentration of the contaminant in the outdoor air rapidly increases. Based on the removal efficiency calculated by the indoor concentration calculation unit 140, the removal efficiency determination unit 142 determines whether or not the contaminant removal efficiency in the contaminant removal filter 110a is reduced. If the removal efficiency determination unit 142 determines that the contaminant removal efficiency in the contaminant removal filter 110a has decreased, the removal notification unit 144 notifies the state notification unit 144 of the decrease in removal efficiency. If the removal efficiency determination unit 142 determines that the contaminant removal efficiency in the contaminant removal filter 110a has not been reduced, the state notification unit 144 does not cause the removal of the reduction efficiency.

FIG. 6 is a flowchart illustrating an example of a flow for notifying a decrease in the removal efficiency of contaminants in the second embodiment.
In the air conditioning control unit 100, the indoor concentration calculation unit 140 inputs the concentration of the pollutant in the indoor air and the concentration of the pollutant in the outdoor air as sensor signals from the second signal input unit 124 (step S130). The indoor concentration calculation unit 140 accumulates the input contaminant concentration in the indoor air and the contaminants in the outdoor air in a storage unit (not shown). The indoor concentration calculation unit 140 determines whether or not a predetermined sampling time has elapsed (step S132). When the predetermined sampling time has not elapsed, the indoor concentration calculation unit 140 continues to accumulate the contaminant concentration in the indoor air and the contaminant in the outdoor air. When the indoor concentration calculation unit 140 determines that the predetermined sampling time has elapsed, the increase in the concentration of the pollutant in the indoor air during the predetermined sampling time and the concentration of the pollutant in the outdoor air during the predetermined sampling time. The amount of increase is calculated. Then, the removal efficiency determination unit 142 calculates the contaminant removal efficiency in the contaminant removal filter 110a based on the increase amount of the contaminant concentration in the indoor air and the increase amount of the contaminant concentration in the outdoor air (step S134). ).

  The removal efficiency determination unit 142 compares the calculated contaminant removal efficiency with a threshold value, and determines whether the calculated contaminant removal efficiency is below the threshold value. The threshold value is set to notify that the contaminant removal efficiency has decreased. The threshold value may be a pollutant removal efficiency set in advance in the pollutant removal filter 110a, or may be a value based on a change in pollutant removal efficiency such as a decrease rate of the pollutant removal efficiency. . When the contaminant removal efficiency falls below the threshold value, the removal efficiency determination unit 142 causes the state notification unit 144 to notify the contaminant removal efficiency. The removal efficiency determination unit 142 may stop the intake of outdoor air by the outside air intake determination unit 128 when it is determined that the contaminant removal efficiency in the contaminant removal filter 110a is reduced.

  Thereby, the state notification unit 144 notifies that the contaminant removal efficiency in the contaminant removal filter 110a is reduced. The notification destination of the state notification unit 144 may be a resident in a predetermined space, a manager of a monitoring system such as HEMS or BEMS, or a maintenance company of a house or building. The status notification unit 144 notifies a decrease in the removal efficiency of contaminants in the form of voice, display, or communication. The state notification unit 144 outputs, for example, an audio display or image display of a decrease in the removal efficiency of the pollutant by an HEMS information presentation device. In addition, the status notification unit 144 transmits information for notifying the computer of the monitoring system such as HEMS or BEMS of a decrease in the removal efficiency of pollutants, for example, in a mail format.

  According to at least one embodiment described above, the outdoor air intake condition calculation unit 122 that compares the temperature / humidity state of the indoor air with the temperature / humidity state of the outdoor air and determines whether to take in outdoor air, Environmental state determination unit 126 that determines whether to take in outdoor air based on the state of pollutants in the air and the state of pollutants in the outdoor air, the result determined by the outdoor air intake condition calculation unit 122, and the environmental state By having an outdoor air intake determination unit 128 that determines whether or not to take in outdoor air based on the result determined by the determination unit 126, the outdoor environment is taken into consideration, and substances that should not be taken into the room are taken into the room. Incorporation can be suppressed.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Air-conditioning control system, 10 ... Air-conditioning control apparatus, 100, 100A ... Air-conditioning control part, 102 ... Indoor air introduction port, 104 ... Harmonic air exhaust port, 106 ... Temperature / humidity sensor for indoor air, 108 ... Contamination for indoor air Substance sensor, 110 ... external air duct, 110a ... pollutant removal filter, 112 ... outdoor air inlet, 114 ... outdoor air temperature / humidity sensor, 116 ... outdoor air pollutant sensor, 120 ... first signal input unit, DESCRIPTION OF SYMBOLS 122 ... Outside air intake condition calculating part, 124 ... 2nd signal input part, 126 ... Environmental state determination part, 128 ... Outside air intake determination part, 130 ... Control output part, 140 ... Indoor concentration calculating part, 142 ... Removal efficiency determination Part, 144... Status notification part

Claims (10)

A first room air detector that detects a temperature and humidity state of room air that is air in a predetermined space;
A first outside air detection unit that detects a temperature and humidity state of outdoor air that is outside the predetermined space;
A second room air detector for detecting the state of pollutants in the room air;
A second outdoor air detector for detecting the state of contaminants in the outdoor air;
The temperature and humidity state detected by the first inside air detection unit, the temperature and humidity state detected by the first outside air detection unit, the state of the contaminant detected by the second inside air detection unit, An air-conditioning control system comprising: a determination unit that determines whether to take outdoor air into the predetermined space based on a state of a contaminant detected by the second outside air detection unit. The determination unit
The temperature / humidity state detected by the first inside air detection unit and the temperature / humidity state detected by the first outside air detection unit are compared to determine whether outdoor air is taken into the predetermined space. 1 determination unit;
Based on the state of the pollutant detected by the second inside air detection unit and the state of the pollutant detected by the second outside air detection unit, whether to take outdoor air into the predetermined space is determined. Two determination units;
The air conditioning control system according to claim 1, comprising: The second determination unit has a concentration of the contaminant, which is the state of the contaminant detected by the second inside air detection unit, is less than a first predetermined value and is detected by the second outside air detection unit. If the concentration of the pollutant is less than the second predetermined value, it is determined that outdoor air is taken into the predetermined space.
The air conditioning control system according to claim 2. The second inside air detection unit and the second outside air detection unit detect the concentration of contaminants peculiar to outdoor air,
The air conditioning control system according to claim 3. The second inside air detection unit detects the concentration of the pollutant peculiar to indoor air as the state of the pollutant,
The second determination unit determines that outdoor air is taken into a predetermined space when the concentration of contaminants peculiar to indoor air is equal to or higher than a third predetermined value.
The air conditioning control system according to claim 3. The first inside air detection unit detects the temperature and humidity of room air,
The first outside air detection unit detects the temperature and humidity of outdoor air,
The first determination unit calculates the enthalpy of room air based on the temperature and humidity of the room air detected by the first room air detection unit, and detects the outdoor air detected by the second room air detection unit. An enthalpy of outdoor air is calculated based on temperature and humidity. When the enthalpy of the indoor air is higher than the enthalpy of the outdoor air, it is determined that the outdoor air is taken into a predetermined space, and the enthalpy of the indoor air is When it is not higher than the enthalpy, it is determined that outdoor air is not taken into the predetermined space.
The air conditioning control system according to any one of claims 2 to 4. The second inside air detection unit and the second outside air detection unit detect the same substance as the state of the contaminant,
Based on the concentration of the contaminant detected at the first timing by the second inside air detection unit and the concentration of the contaminant detected at the second timing after the first timing, the predetermined space is set. Calculate the removal efficiency of the introduced contaminants,
The air conditioning control system according to any one of claims 1 to 5. A first indoor air detector that detects a temperature and humidity state of indoor air that is air in the predetermined space; a first outdoor air detector that detects a temperature and humidity state of outdoor air that is outside the predetermined space; A second inside air detector that detects the state of the pollutant, and a second outside air detector that detects the state of the contaminant in the outdoor air,
The temperature and humidity state detected by the first inside air detection unit, the temperature and humidity state detected by the first outside air detection unit, the state of the contaminant detected by the second inside air detection unit, A determination unit that determines whether to take outdoor air into the predetermined space based on the state of the contaminant detected by the second outside air detection unit;
Air conditioning control device. A first inside air detection unit that detects a temperature and humidity state of room air that is air in a predetermined space, a first outside air detection unit that detects a temperature and humidity state of outdoor air that is air outside the predetermined space, and contamination of room air A step in which a detection result is input from a second inside air detection unit that detects a state of the substance and a second outside air detection unit that detects a state of a contaminant in the outdoor air;
The temperature and humidity state detected by the first inside air detection unit, the temperature and humidity state detected by the first outside air detection unit, the state of the contaminant detected by the second inside air detection unit, An air conditioning control method comprising: determining whether to take outdoor air into the predetermined space based on the state of the pollutant detected by the second outside air detector. On the computer,
A first inside air detection unit that detects a temperature and humidity state of room air that is air in a predetermined space, a first outside air detection unit that detects a temperature and humidity state of outdoor air that is air outside the predetermined space, and contamination of room air A step in which a detection result is input from a second inside air detection unit that detects a state of the substance and a second outside air detection unit that detects a state of a contaminant in the outdoor air;
The temperature and humidity state detected by the first inside air detection unit, the temperature and humidity state detected by the first outside air detection unit, the state of the contaminant detected by the second inside air detection unit, An air conditioning control program for executing a step of determining whether or not to take outdoor air into the predetermined space based on the state of the pollutant detected by the second outside air detection unit.

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