KR20110090744A - Air conditioning control method and air conditioning control apparatus - Google Patents

Abstract

PURPOSE: An air conditioning control method and device are provided to make energy consumption reduction by reducing supply volume and air exhaustion temperature. CONSTITUTION: An air conditioning control method comprises: a step of measuring the dewing temperature of control target chamber; a step of producing a lower limit of the inlet temperature without condensation based on the dew point temperature measured in the control target chamber; a step of setting a setting value of the inlet temperature based on the lower limit of the calculated inlet temperature; and a step of setting a setting value of the air supply air volume based on the lower limit of the calculated inlet temperature.

Description

Air conditioning control method and device {AIR CONDITIONING CONTROL METHOD AND AIR CONDITIONING CONTROL APPARATUS}

The present invention relates to an air conditioning control method and apparatus for controlling a supply air temperature and an air supply air flow amount from an air conditioner for a control target room, using a chamber in which a device which is likely to cause physical damage due to condensation is installed.

Background Art Conventionally, in data centers in which electronic devices such as servers are installed, arrangement of devices in the data center is processed by air supply from an air conditioner (see, for example, Patent Documents 1 and 2).

It is schematically shown in FIG. In FIG. 10, 1 is a data center (control target room), 2 is an air conditioner (cooling device) installed in the data center 1, 3 is a rack containing electronic devices such as a server installed in the data center 1, 4 is The air conditioner control apparatus installed with respect to the air conditioner 2, 5 is an air conditioner which adjusts the temperature and humidity of external air, and supplies it to the data center 1, 6 is discharge | emission of the exhaust from the inside of the data center 1; Is an air supply temperature sensor for detecting the temperature of the air supply to the data center 1 from the air conditioner 2, and 8 is a refrigerant circulation amount adjusting device for adjusting the circulation amount of the refrigerant to the air conditioner 2.

Although the refrigerant | coolant circulation amount regulating device 8 has various operation objects, such as a compressor COMP, an expansion valve, and a hot gas bypass valve, in this example, the example which used the compressor COMP as the refrigerant circulation amount regulating device 8 is an example. Indicates. Hereinafter, the refrigerant circulation amount adjusting device 8 is referred to as COMP8.

In this system, the air conditioner 2 comprises a cooling coil 2-1 and a fan 2-2, in which the fan 3-1 is incorporated. The COMP 8 is provided in the circulation passage of the refrigerant with respect to the cooling coil 2-1. In the air conditioner 2, the air flow rate (air supply air flow rate) of the fan 2-2 is fixed at 100%. The air conditioning control device 4 inputs the measured value tspv of the air supply temperature to the data center 1 from the air supply temperature sensor 7, and the measured value tspv of this air supply temperature coincides with the set value tssp of the predetermined air supply temperature. Adjust the inverter output COMPINV to COMP8. That is, the supply amount of the coolant to the cooling coil 2-1 is controlled by adjusting the% value of the inverter output to the COMP 8 so that the measured value tspv of the air supply temperature and the set value tssp of the air supply temperature coincide.

In this way, in the data center 1, the air supply air volume from the air conditioner 2 is fixed at 100%, the air supply temperature is made constant, and the arrangement of electronic devices such as servers housed in the rack 3 ( I) is to be treated by the air supply from the air conditioner 2.

In the data center 1, if the temperature of the air supply from the air conditioner 2 is too low, dew condensation may occur, which may cause physical damage to the electronic equipment in the data center 1. For this reason, in this system, while the outside air is dehumidified by the external air conditioner 5 and introduced into the data center 1, the set value tssp of the air supply temperature with which there is no condensation in the data center 1 is determined beforehand. Then, the set value tssp of the air supply temperature is set to a fixed value so that constant control of the air supply temperature from the air conditioner 2 is performed. As a technique similar to the constant control of the air supply temperature, Patent Document 1 provides a cooling panel on the side of the rack and controls the temperature of the heating medium supplied to the cooling panel so that the panel surface does not condense.

Japanese Patent Laid-Open No. 2003-35441 Japanese Patent Publication No. 2009-140421

However, in the system shown in FIG. 10, since the set value tssp of the supply air temperature is set to be high enough, the set value tssp of the supply air temperature set to this high is fixed, and the air conditioner 2 is controlled. Since the air supply air volume from the airflow) is fixed at 100%, there is a problem that the loss of energy consumed is large.

This invention is made | formed in order to solve such a subject, and the objective is to provide the air conditioning control method and apparatus which can reduce energy supply air temperature, reduce the air supply air volume by that amount, and can save energy.

In order to achieve this object, the air conditioning control method according to the present invention comprises the steps of measuring the dew point temperature of the room to be controlled, and based on the measured dew point temperature, the lower limit of the air supply temperature at which there is no risk of condensation occurring in the room to be controlled. And calculating the set value of the supply air temperature based on the calculated lower limit value of the supply air temperature, and determining the set value of the air supply air flow amount based on the calculated lower limit value of the supply air temperature.

In the present invention, the dew point temperature of the chamber to be controlled is measured, and the lower limit tsmin1 of the air supply temperature at which there is no fear of dew condensation in the chamber to be controlled is calculated based on the measured value trpv of the dew point temperature. For example, the margin is set to α, and the lower limit tsmin1 of the air supply temperature is calculated as tsmin1 = trpv + α.

Then, the set value tssp of the air supply temperature is determined based on the calculated lower limit value tsmin1 of the air supply temperature. For example, the lower limit of the supply air temperature constrained by the capability of the air conditioner is set to the instrument pharmaceutical supply air temperature lower limit value tsmin2, and this instrument pharmaceutical supply air supply temperature lower limit value tsmin2 is compared with the lower limit value tsmin1 of the calculated supply air temperature. The lower limit is set as the set value tssp of the air supply temperature.

The set value Qssp of the air supply air flow amount is determined based on the calculated lower limit tsmin1 of the air supply temperature. For example, the set value tssp of the supply air temperature is determined based on the calculated lower limit value tsmin1 of the supply air temperature, and from this determined supply temperature tssp, Qssp (CMH) = rated capacity (kW) x 3600 / { -tspsp x specific weight (kg / m 3)}), the set value Qssp of the air supply air flow rate is determined.

In the present invention, instead of measuring the dew point temperature of the control target chamber, the dew point temperature of the exhaust gas from the control target chamber and the dew point temperature of the air supply from the external chamber may be measured. That is, in the present invention, the lower limit value of the air supply temperature may be calculated based on the dew point temperature of the exhaust gas from the control target chamber, or the lower limit value of the air supply temperature may be calculated based on the dew point temperature of the air supply from the external air conditioner. In addition, in this invention, it is not necessary to necessarily provide an external air conditioner, and when not providing an external air conditioner, it is also possible to consider making it calculate the lower limit of the air supply temperature based on the dew point temperature of external air. Moreover, this invention can also be comprised also as an air conditioning control apparatus to which the air conditioning control method mentioned above was applied.

According to the present invention, the dew point temperature (or the dew point temperature of the exhaust, the dew point temperature of the air supply from the external air conditioner, the dew point temperature of the outside air) of the chamber to be controlled is measured and condensation is generated in the control target chamber based on the measured dew point temperature. Since the lower limit value of the supply air temperature which is not likely to occur is calculated, and the set value of the supply air temperature and the supply air flow amount are determined based on the calculated lower limit of the supply air temperature, the supply air temperature is lowered and the supply air flow amount is reduced accordingly. We can save.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows schematically one Embodiment (Embodiment 1) of the air conditioning control system to which the air conditioning control method which concerns on this invention is applied.
FIG. 2 is a functional block diagram showing a main part of an air conditioning control device in the air conditioning control system of Embodiment 1. FIG.
3 is a diagram schematically showing another embodiment (embodiment 2) of the air conditioning control system to which the air conditioning control method according to the present invention is applied.
4 is a functional block diagram showing a main part of an air conditioning control device in the air conditioning control system of the second embodiment.
FIG. 5 is a diagram illustrating setting characteristic I of the air supply temperature and setting characteristic II of the air supply air flow amount used in the air conditioning control system according to the second embodiment.
FIG. 6 is a view showing the setting characteristics I of different supply air temperatures and the setting characteristics II of air supply air flow rates when the lower limit of the air supply temperature is high and low.
It is a figure which shows the example which installed the dew point temperature sensor in the exhaust passage of the exhaust from a data center.
It is a figure which shows the example which installed the dew point temperature sensor in the supply passage of the air supply from the external air conditioner in a data center.
It is a figure which shows the example which installed the dew point temperature sensor in the supply passage | route of the outside air in a data center, when an external air conditioner is not provided.
10 is a view schematically showing a conventional air conditioning control system.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows schematically one Embodiment (Embodiment 1) of the air conditioning control system to which the air conditioning control method which concerns on this invention is applied. In FIG. 1, the same reference numerals as FIG. 10 denote the same or equivalent components as those described with reference to FIG. 10, and a description thereof will be omitted.

In this Embodiment 1, the difference with the conventional system shown in FIG. 10 exists in the function which the air conditioning control apparatus 4 has. In this Embodiment 1, the air conditioning control apparatus 4 is set to 4A, and it distinguishes from the air conditioning control apparatus in the conventional system.

In addition, in this Embodiment 1, the dew point temperature sensor 9 which measures the dew point temperature in the data center 1 is provided in the data center 1, The measured value of the dew point temperature in this dew point temperature sensor 9 is provided. It is assumed that trpv is sent to the air conditioning control device 4A.

In addition, in this Embodiment 1, the fan 2-2 of the air conditioner 2 is provided with the inverter INV which makes the rotation speed variable, and the inverter INV from the air conditioning control device 4A is provided. The air volume (air supply air volume) of the fan 2-2 is controlled by adjusting the% value of the inverter output (fan INV).

The air conditioning control device 4A is realized by hardware consisting of a processor and a storage device, and a program that cooperates with these hardware to realize various functions. As a function unique to the present embodiment, the data center 1 from the air conditioner 2 is provided. It has a function of determining the set value of the air supply temperature and the air supply air flow rate to the inside.

The functional block diagram of the principal part of 4 A of air conditioning control apparatus is shown. Hereinafter, the function of determining the set values of the air supply temperature and the air supply air flow amount included in the air conditioning control device 4A will be described while mixing the functions of the respective parts in this functional block diagram.

The air conditioning control device 4A includes an air supply temperature lower limit value calculation unit 401, a device constraint air supply temperature lower limit value storage unit 402, an air supply temperature set value determination unit 403, an air supply air flow rate set value determination unit 404, A COMPINV output unit 405 and a fan INV output unit 406 are included.

In this example, although the COMPINV output part 405 and the fan INV output part 406 are provided in the air conditioning control device 4A, in a real system, the dedicated controller (not shown) is provided with respect to the air conditioner 2. In FIG. In many cases, when such a dedicated controller is provided for the air conditioner 2, the dedicated controller has a configuration having a COMPINV output section 405 or a fan INV output section 406. In this case, in the air conditioning control device 4A, the COMPINV output unit 405 and the fan INV output unit 406 are removed, and the set value determined by the air supply temperature set value determiner 403 or the air supply air flow rate set value determiner 404 is removed. Sent to the dedicated controller.

The air supply temperature lower limit calculation unit 401 inputs the measured value trpv of the dew point temperature (indoor dew point temperature) in the data center 1 from the dew point temperature sensor 9, and is determined in advance to the measured value trpv of this dew point temperature. The margin α is added to calculate the lower limit tsmin1 (tsmin1 = trpv + α) of the air supply temperature at which there is no risk of condensation occurring in the data center 1. In other words, the lower limit value tsmin1 of the air supply temperature at which there is no fear that dehumidification (including dehumidification in the coil 2-1) occurs in the data center 1 by the air supply from the air conditioner 2 is calculated. The margin α may be determined by determining how much a person is from the indoor CO ₂ concentration (estimating the amount of generated water in the room) and making it variable. In addition, not only the CO ₂ concentration but also information such as a security system may determine how much a person is.

The air supply temperature set value determination unit 403 inputs the lower limit value tsmin1 of the air supply temperature calculated by the air supply temperature lower limit value calculation unit 401 and inputs the lower limit value tsmin1 of the air supply temperature to the device constraint air supply temperature lower limit storage unit 402. The lower limit of the supply air supply temperature is compared with the stored device pharmaceutical supply air temperature lower limit value tsmin2, and the set value tssp of the supply air temperature. Here, the apparatus pharmaceutical supply air temperature lower limit value tsmin2 is the lower limit of the air supply temperature restricted by the capability of the air conditioner 2, and points out the lower limit of the air supply temperature range described in a catalog etc. here.

The air supply air flow rate setting value determining unit 404 takes the input value tssp of the air supply temperature determined by the air supply temperature setting value determining unit 403, and Qssp (CMH) = rated capacity (kW) x 3600 / { tssp) x specific weight (kg / m <3>)} determines the set value Qssp of the air supply air flow rate. In the calculation formula of the set air supply air quantity Qssp, "assuming suction temperature" means the suction temperature assumed at the time of the rated operation of the air conditioner 2, and refers to the rated suction time temperature described in a catalog etc. In addition, "rating capacity" is the rated cooling ability of the air conditioner 2.

The COMPINV output unit 405 takes as input the measured value tspv of the air supply temperature from the air supply temperature sensor 7 and the set value tssp of the air supply temperature determined by the air supply temperature set value determination unit 403. Adjust the inverter output COMPINV to COMP 8 so that the measured value tspv of the supply temperature coincides with the set value tssp of the supply temperature.

The fan INV output unit 406 inputs the set value Qssp of the air supply air flow amount determined by the air supply air flow rate setting value determination unit 404, and sets the air supply airflow amount Qs from the fan 2-2 to Qssp. Adjust the inverter output (fan INV) for.

Thus, in this embodiment, air supply which does not have a possibility of dew condensation in the data center 1 as a value as low as possible from the dew point temperature trpv in the data center 1 measured by the dew point temperature sensor 9 is as low as possible. The set value tssp of the temperature is determined, and the set value Qssp of the air supply air quantity suitable for the set value tssp of the air supply temperature is determined, so that the air supply temperature is lowered, and the air supply air volume is reduced by that, and energy saving can be achieved.

In the present embodiment, when calculating the set value Qssp of the air supply air flow amount, the calculated value may be added to the calculated set value Qssp of the air supply air flow amount. Depending on the load of the electronic equipment accommodated in the rack 3, the inside of the data center 1 may become excessively hot. However, by adding the calculated value to the set value Qssp of the air supply air flow amount, the calculated value is slightly increased. 1) It becomes possible to improve the problem that the inside becomes too hot.

Embodiment 2

3 is a diagram schematically showing another embodiment (embodiment 2) of the air conditioning control system to which the air conditioning control method according to the present invention is applied. In this Embodiment 2, in addition to the dew point temperature sensor 9 which measures the dew point temperature in the data center 1, the data center 1 measures the temperature of the entrance side of the rack 3 as the present temperature ( 10) is provided, and the measured value trpv of the dew point temperature in the dew point temperature sensor 9 and the measured value tpv of the present temperature in the temperature sensor 10 are sent to the air conditioning control device 4 (4B).

In addition, also in the second embodiment, an inverter INV having a variable rotational speed is provided in the fan 2-2 of the air conditioner 2, similarly to the first embodiment, and is provided from the air conditioning control device 4B. By adjusting the% value of the inverter output (fan INV) with respect to the inverter INV, the air volume (air supply air volume) of the fan 2-2 is controlled.

The functional block diagram of the principal part of the air conditioning control device 4B is shown in FIG. Hereinafter, the function of determining the set values of the air supply temperature and the air supply air flow amount included in the air conditioning control device 4B will be described while mixing the functions of the respective parts in this functional block diagram.

The air conditioning control device 4B includes a supply air temperature lower limit value calculation unit 411, a device pharmaceutical supply air temperature lower limit value storage unit 412, a supply air temperature lower limit value determination unit 413, a request temperature storage unit 414, and an air supply The temperature set value determiner 415, the air supply air flow rate set value determiner 416, a COMPINV output unit 417, and a fan INV output unit 418 are included. In the required temperature storage unit 414, the required value for the current temperature tpv measured by the temperature sensor 10 is stored as the required temperature tsp.

The air supply temperature lower limit calculation unit 411 is configured similarly to the air supply temperature lower limit calculation unit 401 according to the first embodiment to determine the dew point temperature (dew point temperature in the room) in the data center 1 from the dew point temperature sensor 9. The measured value trpv is taken as an input, and a predetermined margin α is added to the measured value trpv of the dew point temperature to calculate a lower limit value tsmin1 (tsmin1 = trpv + α) of the air supply temperature at which no condensation may occur in the data center 1. do.

The air supply temperature lower limit value determination unit 413 inputs the lower limit value tsmin1 of the air supply temperature calculated by the air supply temperature lower limit calculation unit 411, and inputs the lower limit value tsmin1 of the air supply temperature to the device constraint air supply temperature lower limit storage unit 412. The lower limit of the supply air temperature is compared with the lower limit value tsmin of the air supply temperature by comparing the stored device pharmaceutical supply air temperature lower limit value tsmin2.

The air supply temperature set value determining unit 415 stores the lower limit value tsmin of the air supply temperature determined by the air supply temperature lower limit value determining unit 413, the current temperature tpv from the temperature sensor 10, and the request temperature storage unit 414. The temperature tsp is taken as an input, and the set value tssp of the air supply temperature is determined according to the setting characteristic I of the air supply temperature shown in FIG. 5.

That is, using the lower limit tsmin of the air supply temperature as a control parameter, in the range where the current temperature tpv is higher than tx, the set value tssp of the air supply temperature is fixed as the lower limit tsmin of the air supply temperature, while the current temperature tpv is lower than tx. As the difference with the required temperature tsp increases, the set value tssp of the air supply temperature is increased.

By setting this supply air temperature as the setting characteristic I, when the load in the data center 1 decreases and the present temperature tpv becomes lower than tx, the setting value tssp of air supply temperature will rise and the ability of the air conditioner 2 will fall. This prevents overcooling in the data center 1 and saves energy.

The air supply air flow rate setting value determining unit 416 stores the lower limit value tsmin of the air supply temperature determined by the air supply temperature lower limit value determining unit 413, the current temperature tpv from the temperature sensor 10, and the request temperature storage unit 414. The temperature tsp is taken as an input, and the set value Qssp of the air supply air flow amount is determined according to the setting characteristic II of the air supply air flow amount shown in FIG. 5.

That is, using the lower limit value tsmin of the supply air temperature as a control parameter, before the set value tssp of the supply air temperature is fixed to tsmin, the set value Qssp of the supply air volume is fixed to the predetermined lower limit, while the set value tssp of the supply air temperature is fixed to tsmin. After that, as the difference with the required temperature tsp increases, the set value Qssp of the air supply air flow amount is increased.

When the load in the data center 1 is small by setting this characteristic of the air supply air flow amount, the set value Qssp of the air supply air flow amount is fixed to a lower limit to achieve energy saving, while the load in the data center 1 is achieved. When is increased and the current temperature tpv is higher than tx, the set value Qssp of the air supply air flow rate is increased to prevent the inside of the data center 1 from becoming hot.

The COMPINV output unit 417 takes as input the measured value tspv of the air supply temperature from the air supply temperature sensor 7 and the set value tssp of the air supply temperature determined by the air supply temperature set value determination unit 415. Adjust the inverter output COMPINV to COMP 8 so that the measured value tspv of the supply temperature coincides with the set value tssp of the supply temperature.

The fan INV output unit 406 inputs the set value Qssp of the air supply air flow amount determined by the air supply air flow rate setting value determination unit 416, and sets the air supply airflow amount Qs from the fan 2-2 to Qssp. Adjust the inverter output (fan INV) for.

FIG. 6 shows setting characteristic I of supply air temperature and setting characteristic II of air supply air flow amount which change with the lower limit tsmin of air supply temperature as a control parameter. The characteristics I _H and II _H show the setting characteristics of the air supply temperature and the air flow rate setting characteristics when the lower limit tsmin of the air supply temperature is high, and the characteristics I _L and II _{L set} the air supply temperature when the lower limit tsmin of the air supply temperature is low. The characteristic and the setting characteristic of the air supply air volume are shown. From such a change in the setting characteristics, it can be seen that by lowering the lower limit value tsmin of the air supply temperature, the air supply air volume (output of the fan INV) can be suppressed even with the same degree of cooling demand.

In Embodiments 1 and 2 described above, the dew point temperature sensor 9 is installed in the data center 1 to measure the dew point temperature in the room. However, the exhaust air is discharged by the exhaust fan 6 from the inside of the data center 1. The dew point temperature may be measured, or the dew point temperature of the air supply from the air conditioner 5 to the data center 1 may be measured.

That is, when Embodiment 1 is taken as an example, as shown in FIG. 7, the dew point temperature sensor 9 is provided in the discharge passage of the exhaust by the exhaust fan 6 from inside the data center 1, and this dew point temperature is set. The lower limit value tsmin1 of the air supply temperature may be calculated from the measured value trpv of the dew point temperature at the sensor 9, and as shown in FIG. 8, a dew point is provided in the supply passage of the air supply from the air conditioner 5 to the data center 1. The temperature sensor 9 may be provided and the lower limit tsmin1 of the air supply temperature may be calculated from the measured value trpv of the dew point temperature in the dew point temperature sensor 9.

In addition, although the outer shell 5 was provided in embodiment mentioned above, the outer shell 5 does not necessarily need to be installed. In the case where the outer shell machine 5 is not provided, for example, in Embodiment 1, as shown in FIG. 9, the dew point temperature sensor 9 is provided in the supply passage of the outside air to the data center 1, and this dew point is provided. It is also conceivable to calculate the lower limit tsmin1 of the air supply temperature from the measured value trpv of the dew point temperature in the temperature sensor 9.

In addition, in the above-described embodiment, the dew point temperature sensor 9 is provided to measure the dew point temperature. However, the dew point temperature may be calculated from the measured temperature and humidity by measuring the temperature and the humidity. In the present invention, the concept of measuring the dew point temperature also includes calculating the dew point temperature from the measured temperature and humidity.

In addition, in the above-mentioned embodiment, although the refrigerant | coolant circulation amount control device 8 is made into the compressor COMP, as mentioned above, various operation objects, such as an expansion valve and a hot gas bypass valve, are used as the refrigerant | coolant circulation amount control device 8 as mentioned above. Of course it can be considered.

The air conditioning control method and apparatus of the present invention is a room to which a device which is likely to cause physical damage due to dew condensation is set as a control target room, and an air conditioning control method for controlling the air supply temperature and the air supply air volume from the air conditioner of the control target room; As an apparatus, it is possible to apply various rooms, such as a data center in which electronic devices, such as a server, were installed as a room to be controlled.

1: data center 2: air conditioner (cooling unit)
2-1: cooling coil 2-2: fan
INV: Inverter
3: rack 3-1: fan (built-in fan)
4 (4A, 4B): air conditioning control device 5: external air conditioner
6: exhaust fan 7: air supply temperature sensor
8: refrigerant circulation amount control device (COMP)
9: dew point temperature sensor 10: temperature sensor
401: air supply temperature lower limit calculation unit
402: device pharmaceutical supply air temperature lower limit storage unit
403: air supply temperature set value determining unit
404: air supply air flow rate setting unit
405: COMPINV output unit 406: fan INV output unit
411: air supply temperature lower limit calculation unit
412: device pharmaceutical supply temperature lower limit storage unit
413: air supply temperature lower limit determination unit
414 required temperature storage
415: air supply temperature set value determining unit
416: air supply air flow rate setting unit
417: COMPINV output 418: fan INV output

Claims (6)

As an air-conditioning control method which controls the air supply temperature and air supply air volume from the air conditioner with respect to this control target room, the room to which the apparatus which might cause physical damage by dew condensation is controlled is provided,
Measuring a dew point temperature of the chamber to be controlled;
Calculating a lower limit value of the air supply temperature at which there is no risk of condensation occurring in the control chamber based on the measured dew point temperature;
Determining a set value of the air supply temperature based on the calculated lower limit of the air supply temperature;
Determining a set value of the air supply air quantity based on the calculated lower limit of the air supply temperature
Air conditioning control method comprising a. The method of claim 1, wherein the determining of the set value of the air supply temperature,
The lower limit of the supply air temperature constrained by the capability of the air conditioner is defined as the lower limit of the supply limit of the supply pharmaceutical temperature, and the lower limit of the supply supply temperature is compared with the lower limit of the supply supply temperature. The air conditioning control method characterized by determining as a set value. The air conditioner according to claim 1 or 2, wherein the dew point temperature of the exhaust from the control target chamber and the outside air are processed and supplied to the control target chamber instead of measuring the dew point temperature of the control target chamber. And measuring a dew point temperature of the dew point temperature of the air supply from the air blower and the dew point temperature of the outside air. As an air-conditioning control device which controls the air supply temperature and the air supply air volume from the air conditioner with respect to this control target room, the room to which the apparatus which might cause physical damage by dew condensation is controlled is provided,
Dew point temperature measuring means for measuring a dew point temperature of the control room;
Air supply temperature lower limit value calculation means for calculating a lower limit of the air supply temperature at which there is no risk of condensation occurring in the control target chamber based on the measured dew point temperature;
Air supply temperature set value determining means for determining a set value of the air supply temperature based on the calculated lower limit of the air supply temperature;
Air supply air flow rate setting value determination means which determines the setting value of the air supply air flow amount based on the calculated lower limit value of the air supply air temperature.
Air conditioning control device comprising a. The air supply temperature set value determining means according to claim 4,
The lower limit of the supply air temperature constrained by the capability of the air conditioner is defined as the lower limit of the supply limit of the supply pharmaceutical temperature, and the lower limit of the supply supply temperature is compared with the lower limit of the supply supply temperature. The air conditioning control apparatus characterized by determining as a set value. The method according to claim 4 or 5, wherein the dew point temperature of the exhaust from the control target chamber and the outside air are processed and supplied to the control target chamber instead of the dew point temperature measuring means for measuring the dew point temperature of the control target chamber. And a dew point temperature measuring means for measuring any dew point temperature among the dew point temperature of the air supply from the early stage and the dew point temperature of the outside air.

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