JP2000310440A - Air conditioning control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a lowering of air conditioning cost by restricting the consumption of energy in dehumidification. SOLUTION: The present status point of an air conditioning control area determined by a room temperature Tr and an absolute humidity Ar in an air diagram is obtained. If the status point exists in an area where the absolute humidity value Ar (T0, R0)=Ar1 or more is given when the room temperature Tr is at a set target value T0 of the room temperature and the room humidity (relative humidity) Rr is at a set value R0 of the room humidity, the absolute humidity value Ar (T1, R0)=Ar2 or less while the value exceeds the set value R0 of the room humidity at the relative humidity of 100% or less when the room temperature Tr is at a set upper limit value T1 of the room temperature and the room humidity RR is at the set value R0 of the room humidity, a control of heating is performed to accomplish dehumidification so that the status point (P1) is positioned on a line L1 of the set value R0 of the room humidity.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for controlling air conditioning in a room such as a clean room, a museum, a storage room, and the like, in which the indoor environment is required to be kept at a constant temperature and humidity.

[0002]

2. Description of the Related Art In biological clean rooms such as operating rooms, laboratory animal breeding rooms, and biotechnology laboratories, and in industrial clean rooms, museums, and storage rooms provided in factories of the electronics industry and the precision machinery industry, the purpose is as follows. In addition, the indoor environment such as temperature and humidity must be kept almost constant.

Therefore, a constant-temperature and constant-humidity air-conditioning control system is used for the purpose of maintaining the temperature and humidity of the indoor environment.
FIG. 5 is a diagram showing a main part of a conventional constant temperature / humidity air conditioning control system. In the figure, 1 is an air conditioner, 2 is a controlled room (air conditioning control area), 3 is a control device, 4 and 5 are control valves, 6 is a temperature sensor disposed in the controlled room 2, and 7 is a controlled room. It is a humidity sensor (relative humidity sensor) arranged in the room 2. The air conditioner 1 includes a cooling heat exchanger (cooling coil) 1-1, a heating heat exchanger (heating coil) 1-2, a humidifier 1-3, and a blower 1-4. The control valve 4 has a cooling coil 1-
1 is provided in the supply passage for cold water. The control valve 5 is provided in a supply path of hot water to the heating coil 1-2.

In this constant temperature / humidity air conditioning control system,
In the control device 3, a room temperature setting target value T0, a room temperature setting upper limit value T1, and a room humidity (relative humidity) setting value R0 are set. The control device 3 inputs the current room temperature Tr from the temperature sensor 6 and the current room humidity (relative humidity) Rr from the humidity sensor 7 and controls the room humidity Rr to match the room humidity set value R0. And the room temperature Tr
Is controlled within an allowable temperature range defined by the room temperature setting target value T0 and the room temperature setting upper limit value T1.

Here, for example, the current state point of the controlled room 2 determined by the room temperature (dry-bulb temperature) Tr and the absolute humidity Ar in the psychrometric chart is point P1 (see FIG. 6). Assume that it is necessary. In this case, the control device 3
By the heating control, the room temperature Tr is set to the room temperature set target value T.
Using the cooling coil 1-1 up to the dew point temperature Tsp1 (P3 point) corresponding to the absolute humidity Ar (T0, R0) when the room humidity Rr is 0 and the room humidity Rr is the indoor humidity set value R0 (point P4). After dehumidifying by temporarily cooling the intake air in the air conditioner 1, the intake air is cooled by the heating coil 1.
The temperature is heated (reheated) to the indoor temperature set target value T0 using -2 (point P4) and supplied to the controlled room 2 as conditioned air.

[0006]

However, in such a conventional constant-temperature and constant-humidity air-conditioning control system, since dehumidification is performed by cooling / heating control, a large amount of energy is consumed and the cost of air-conditioning is increased. It has become.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and an object of the present invention is to provide an air-conditioning control capable of suppressing energy consumption during dehumidification and reducing air-conditioning costs. It is to provide a method.

[0008]

In order to achieve such an object, a first invention (the invention according to claim 1) is to provide an air conditioning control area which is determined by an indoor temperature and an absolute humidity in an air chart. A state point is determined, and this state point is equal to or higher than the first absolute humidity value when the room temperature is the temperature setting target value and the relative humidity is the relative humidity setting value. Second when the humidity is the relative humidity set value
In the region (region A shown in FIG. 1) that is not more than the absolute humidity value and is not more than 100% relative humidity and exceeds the set value of relative humidity, this state point is set to a line of the set value of relative humidity (L1 shown in FIG. 1). The heating of the room temperature in the air-conditioning control area is controlled so as to be positioned above. According to the present invention, when the current state point of the air-conditioning control area in the psychrometric chart is in the area A, the room temperature of the air-conditioning control area is set such that this state point is located on the line L1 of the relative humidity set value. Is controlled by heating to achieve dehumidification.

A second invention (an invention according to claim 2) obtains a current state point of an air-conditioning control area determined by an indoor temperature and an absolute humidity in a psychrometric chart. Value, the relative humidity exceeds the absolute humidity value when the relative humidity is the set value, and is in an area (area B shown in FIG. 1) of 100% or less in relative humidity. The cooling / heating control of the indoor temperature of the air-conditioning control area is performed so as to be located at the intersection (point P6 shown in FIG. 1) with the relative humidity set value. According to this invention, when the current state point of the air-conditioning control area in the psychrometric chart is in the area B, the air-conditioning is performed such that this state point is located at the intersection P6 between the temperature setting upper limit value and the relative humidity setting value. Cooling and heating control of the room temperature in the control area
Dehumidification is achieved.

A third invention (an invention according to claim 3) obtains a current state point of an air-conditioning control area determined by the room temperature and the absolute humidity in the psychrometric chart. A second absolute value when the room temperature is equal to or higher than the first absolute humidity value when the relative humidity is the relative humidity setting target value and the room temperature is the temperature setting target value and the relative humidity is the relative humidity setting upper limit value. Humidity value or less and relative humidity 100%
In the case where the temperature is below the temperature setting target value (region E shown in FIG. 3), the state point is located on the temperature setting target value line (L3 shown in FIG. 3). The room temperature is controlled to be heated, and the state point exceeds the second absolute humidity value when the room temperature is the temperature setting target value and the relative humidity is the humidity setting upper limit value, and the room temperature is the temperature setting upper limit value. Is less than or equal to the third absolute humidity value when the relative humidity is the relative humidity setting upper limit value, and the relative humidity is 100
% Or less and exceeds the relative humidity setting upper limit (region F shown in FIG. 3), the air conditioning is performed such that this state point is located on the line of relative humidity setting upper limit (L2 shown in FIG. 3). The heating of the room temperature in the control area is controlled. According to the present invention, when the current state point of the air-conditioning control area in the psychrometric chart is in the region E, the room temperature of the air-conditioning control area is set so that this state point is located on the line L3 of the temperature setting target value. Is controlled by heating to achieve dehumidification. When the current state point of the air-conditioning control area in the psychrometric chart is in the area F, the indoor temperature of the air-conditioning control area is controlled so that the state point is located on the line L2 of the relative humidity set upper limit. Then, dehumidification is achieved.

A fourth invention (an invention according to claim 4) obtains a current state point of an air-conditioning control area determined by a room temperature and an absolute humidity in a psychrometric chart. Value, the relative humidity exceeds the absolute humidity value when the relative humidity is the upper limit of the relative humidity setting, and the relative humidity is 100
% (Region G shown in FIG. 3), the air-conditioning control area is positioned such that this state point is located at the intersection (point P23 shown in FIG. 3) between the temperature setting upper limit and the relative humidity setting upper limit. The cooling and heating control of the room temperature is performed. According to the present invention, when the current state point of the air-conditioning control area in the psychrometric chart is in the area G, this state point is set to the intersection P2 of the temperature setting upper limit value and the relative humidity setting upper limit value.
The indoor temperature of the air-conditioning control area is controlled to be cooled and heated so as to be located at No. 3, thereby achieving dehumidification.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail based on embodiments. [Embodiment 1] In Embodiment 1, the system configuration is the same as the conventional one shown in FIG. 5, but the function of the control device 3 is different. The control device in this case is designated as 3-1 to be distinguished from the conventional control device 3. The control device 3-1 determines in which region (regions A to D) the current state point of the controlled room 2 is in the psychrometric chart (see FIG. 1), and according to the determined region, the air conditioner 1 Control. FIG.
Is a flowchart showing a specific processing operation performed by the control device 3-1.

[When in the area A] The control device 3-1
Current room temperature Tr and humidity sensor 7 from temperature sensor 6
And the current room humidity Rr from step 20 (step 20).
1) The current absolute humidity Ar in the controlled room 2 is obtained based on the room temperature Tr and the room humidity Rr (step 2).
02), it is determined which of the regions A to D is the state point in the psychrometric chart determined by the room temperature Tr and the absolute humidity Ar (step 203).

Now, the state point of the controlled room 2 is P1 in the area A.
Assume that there is a point. That is, when the room temperature Tr is the room temperature set target value T0 and the room humidity Rr is the room humidity set value R0 (point P4), the absolute humidity value Ar (T0,
R0) = Ar1 or more, the absolute humidity value Ar (T1, R0) = A when the indoor temperature Tr is the indoor temperature set upper limit T1 and the indoor humidity Rr is the indoor humidity set value R0 (point P6).
A region that is equal to or less than r2 and equal to or less than 100% relative humidity and exceeds the room humidity set value R0 is defined as a region A, and P1 in this region A
It is assumed that there is a state point of the controlled room 2 at the point.

In this case, the control device 3-1 controls the heating coil 1-2 so that the air taken in the air conditioner 1 is controlled by the heating control so that the state point P1 is positioned on the line L1 of the room humidity set value R0. Heating (Steps 204 and 2)
05). Due to this heating, the room temperature Tr rises, the room humidity (relative humidity) Rr decreases, and the room humidity set value R0
It is adjusted to. That is, in this case, the control device 3-
By the heating control by 1, the controlled room 2 is dehumidified.

Here, dehumidification by conventional cooling / heating control
And dehumidification by heating control in the present embodiment,
Let's compare the energy consumption. Conventional cooling / heating system
In FIG. 6, the room temperature Tr at the point P1 in FIG.
℃, room temperature Tr at P2 point 11.3 ℃, at P3 point
The indoor temperature Tr is 9.5 ° C., and the indoor temperature Tr at the point P4 is 2
When the temperature is 2 ° C., the cooling from the point P1 to the point P2 is 1.3.
8kcal / m^Three/ H, for cooling from point P2 to point P3
1.02 kcal / m ^Three/ H, from point P3 to point P4
3.03 kcal / m for heating^Three/ H energy required
And a total of 5.43 kcal / m^Three/ H energy
Need

On the other hand, in the heating control of the present embodiment, when the room temperature Tr at the point P1 in FIG. 1 is set to 17 ° C., the heating from the point P1 to the point P5 is 1.71 kca.
1 / m ³ / h energy is required, which is 3.72 kcal more than the conventional cooling / heating control method.
/ M ³ / h.

[When in the area B] It is assumed that the state point of the controlled room 2 is at point P7 in the area B. That is, the room temperature Tr is the room temperature setting upper limit value T1 and the room humidity R
When r is the room humidity set value R0 (point P6), a region that exceeds the absolute humidity value Ar (T1, R0) = Ar2 and has a relative humidity of 100% or less is defined as a region B.
It is assumed that there are seven state points of the controlled room 2.

In this case, the control device 3-1 controls the cooling coil 1-1 such that the state point P7 is located at the intersection P6 of the room temperature set upper limit value T1 and the room humidity set value R0 by cooling / heating control. After dehumidifying the intake air in the air conditioner 1 to the point P9 (the dew point temperature Tsp2 corresponding to the absolute humidity Ar (T1, R0)) by using, the intake air is cooled by the heating coil 1-2. To heat (reheat) to the room temperature setting upper limit value T1 (steps 204 and 2).
06).

Here, conventional dehumidification by cooling / heating control
And the dehumidification by cooling / heating control in the present embodiment.
Let's compare the energy consumption. Conventional cooling
In the heating control, the room temperature Tr at the point P7 in FIG.
Room temperature Tr at 17 ° C, P8 point is 13.5 ° C, P3 point
The indoor temperature Tr at 9.5 ° C. and the indoor temperature Tr at point P4
Is 22 ° C, cooling from point P7 to point P8
0.85 kcal / m^Three/ H, from P8 point to P3 point
2.34 kcal / m for cooling ^Three/ H, P3 point to P4 point
3.03 kcal / m for heating up to^Three/ H energy
And a total of 6.22 kcal / m^Three/ H
Needs energy.

On the other hand, in the cooling / heating control of the present embodiment, the room temperature Tr at the point P7 in FIG.
° C, when the indoor temperature Tr at the point P8 is 13.5 ° C. and the indoor temperature Tr at the point P6 is 24 ° C., the cooling from the point P7 to the point P8 is 0.85 kcal / m ³ / h. P
Cooling up to 9 points 1.32kcal / m ³ / h, the heating from P9 point to point P6 well only require energy 3.08kcal / m ³ / h, the method according to the conventional cooling and heating control Energy saving of 0.97 kcal / m ³ / h.

[Case in Region C] It is assumed that the state point of the controlled room 2 is at a point P10 in the region C. That is, when the room temperature Tr is the room temperature set target value T0 and the room humidity Rr is the room humidity set value R0 (point P4), the room temperature Tr is not less than the absolute humidity value Ar (T0, R0) = Ar1.
Is the room temperature setting upper limit value T1 and the room humidity Rr is the room humidity setting value R0 (point P6), the absolute humidity value Ar
(T1, R0) = Ar2 or less and indoor humidity set value R
It is assumed that a region below 0 is a region C, and a state point of the controlled room 2 is at a point P10 in the region C.

In this case, the control device 3-1 changes the state point P10 to the line L1 of the room humidity set value R0 by the cooling control.
The air taken into the air conditioner 1 is cooled using the cooling coil 1-1 so as to be positioned above (steps 204 and 20).
7). By this cooling, the room temperature Tr decreases, the room humidity Rr increases, and is adjusted to the room humidity set value R0. That is, in this case, the controlled room 2 is humidified by the cooling control by the control device 3-1 until Rr = R0.

[When in the area D] It is assumed that the state point of the controlled room 2 is at the point P11 in the area D. That is, when the room temperature Tr is the room temperature set target value T0 and the room humidity Rr is the room humidity set value R0 (point P4), the absolute humidity value Ar (T0, R0) is lower than Ar1 and the relative humidity 100 % Is defined as a region D, and a state point of the controlled room 2 is assumed to be at a point P11 in the region D.

In this case, the control device 3-1 controls the humidification / cooling control so that the state point P11 is located at the intersection P4 of the room temperature set target value T0 and the room humidity set value R0.
The intake air in the air conditioner 1 is humidified using the humidifier 1-3 until the absolute humidity Ar1 is reached (point P12).
The temperature is cooled to the room temperature set target value T0 using the cooling coil 1-1 (steps 204 and 208).

Note that the state point of the controlled room 2 is P
If it is at point 13, only humidification control to the absolute humidity value Ar1 is performed. If it is at the point P14, the absolute humidity Ar
1 and the heating control to the indoor temperature setting target value T0 (humidifying / heating control).

[Second Embodiment] In the second embodiment, the system configuration is the same as the conventional one shown in FIG. 5, but the function of the control device 3 is different. The control device in this case is shown as 3-2 in distinction from the conventional control device 3 and the control device 3-1 of the first embodiment. Control device 3
For -2, an indoor humidity setting upper limit R1 is set in addition to the indoor temperature setting target value T0, the indoor temperature setting upper limit T1, and the indoor humidity setting value (indoor humidity setting target value) R0.

The control device 3-2 inputs the current room temperature Tr from the temperature sensor 6 and the current room humidity Rr from the humidity sensor 7, and converts the room humidity Rr into the room humidity setting target value R.
0 and the room humidity setting upper limit R1 are controlled to be within an allowable relative humidity range, and the room temperature Tr is set within an allowable temperature range defined by the room temperature setting target value T0 and the room temperature setting upper limit T1. Control.

The control device 3-2 determines in which area (areas E to J) the current state point of the controlled room 2 is in the psychrometric chart (see FIG. 3). The air conditioner 1 is controlled accordingly. FIG. 4 is a flowchart showing a specific processing operation performed by the control device 3-2.

[When in the area E] The controller 3-2
Current room temperature Tr and humidity sensor 7 from temperature sensor 6
And the current room humidity Rr from step (step 40).
1) The current absolute humidity Ar in the controlled room 2 is obtained based on the room temperature Tr and the room humidity Rr (step 4).
02), it is determined which of the regions E to J is the state point in the psychrometric chart determined by the room temperature Tr and the absolute humidity Ar (step 403).

Now, the state point of the controlled room 2 is P1 in the area E.
It is assumed that there are six points. That is, the absolute humidity Ar when the room temperature Tr is the room temperature setting target value T0 and the room humidity Rr is the room humidity setting target value R0 (point P30).
When (T0, R0) = Ar4 or more and the indoor temperature Tr is the indoor temperature setting target value T0 and the indoor humidity Rr is the indoor humidity setting upper limit R1 (point P36), the absolute humidity value Ar (T
(0, R1) = Ar4 or less and a relative humidity of 100% or less and an area below the indoor temperature setting target value T0 is an area E,
It is assumed that there is a state point of the controlled room 2 at a point P16 in the area E.

In this case, the control device 3-2 controls the intake air in the air conditioner 1 to the heating coil 1-2 so that the state point P16 is positioned on the line L3 of the room temperature set target value T0 by the heating control. (Step 40)
4,405). By this heating, the room temperature Tr rises and is adjusted to the room temperature setting target value T0, and the room humidity (relative humidity) Rr decreases. That is, in this case, the controlled room 2 is dehumidified by the heating control by the control device 3-2.

[When in the area F] It is assumed that the state point of the controlled room 2 is at point P18 in the area F. That is, when the room temperature Tr is the room temperature setting target value T0 and the room humidity Rr is the room humidity setting upper limit R1 (point P36).
Is greater than the absolute humidity value Ar (T0, R1) = Ar4 and the room temperature Tr is the room temperature setting upper limit value T1 and the room humidity R
When r is the indoor humidity setting upper limit R1 (point P23), an area where the absolute humidity value Ar (T1, R1) = Ar6 or less and the relative humidity is 100% or less and exceeds the indoor humidity setting upper limit R1 is defined as an area F. It is assumed that the state point of the controlled room 2 is at point P18 in the area F.

In this case, the control device 3-2 controls the heating air to be supplied to the heating coil 1-2 so that the state point P18 is positioned on the line L2 of the room humidity setting upper limit R1 by heating control. (Step 40)
4,406). Due to this heating, the room temperature Tr increases, the room humidity Rr decreases, and is adjusted to the room humidity set upper limit value R1. That is, in this case, the control device 3-2
, The controlled room 2 is dehumidified until Rr = R1.

[When in the area G] It is assumed that the state point of the controlled room 2 is at point P20 in the area G. That is, when the room temperature Tr is the room temperature setting upper limit T1 and the room humidity Rr is the room humidity setting upper limit R1 (point P23).
It is assumed that a region exceeding the absolute humidity value Ar (T1, R1) = Ar6 and having a relative humidity of 100% or less is a region G, and a state point of the controlled room 2 is located at a point P20 in the region G.

In this case, the control device 3-2 performs the cooling / heating control so that the state point P20 is located at the intersection P23 of the room temperature setting upper limit T1 and the room humidity setting upper limit R1. 1, the air taken in the air conditioner 1 is dehumidified by cooling it to a point P22 (dew point temperature Tsp3 corresponding to the absolute humidity Ar (T1, R1)), and then the air taken in is heated by a heating coil 1-2. Is used to heat (reheat) to the room temperature setting upper limit value T1 (steps 404 and 407).

[When in the area H] It is assumed that the state point of the controlled room 2 is at point P24 in the area H. That is, when the room temperature Tr is the room temperature setting upper limit T1 and the room humidity Rr is the room humidity setting target value R0 (point P35).
The absolute humidity value Ar (T1, T0) = Ar5 or more and the room temperature Tr is the room temperature setting upper limit value T1 and the room humidity Rr
Is the room humidity setting upper limit value R1 (point P23), an area where the absolute humidity value Ar (T1, R1) = Ar6 or less and exceeds the room temperature setting upper limit value T1 is defined as a region H, and P24 in this region H It is assumed that there is a state point of the controlled room 2 at the point.

In this case, the control device 3-2 controls the cooling air by the cooling coil 1-1 such that the state point P24 is positioned on the line L4 of the room temperature setting upper limit value T1 by the cooling control. (Step 40)
4,408). By this cooling, the room temperature Tr decreases, is adjusted to the room temperature set upper limit value T1, and the room humidity Rr increases. That is, in this case, the control device 3-2
Is controlled, the controlled room 2 is humidified.

[Case in Region I] It is assumed that the state point of the controlled room 2 is at a point P26 in the region I. That is, when the room temperature Tr is the room temperature setting target value T0 and the room humidity Rr is the room humidity setting target value R0 (point P30).
If the absolute humidity value Ar (T0, R0) = Ar3 or more, the room temperature Tr is the room temperature setting upper limit value T1, and the room humidity R
When r is the indoor humidity setting target value R0 (point P35), an area where the absolute humidity value is lower than the absolute humidity value Ar (T0, R0) = Ar5 and lower than the indoor humidity setting target value R0 is defined as an area I. It is assumed that there is a state point of the controlled room 2 at point P26.

In this case, the control device 3-2 controls the cooling air by the cooling coil 1-1 so that the state point P26 is positioned on the line L1 of the room humidity setting target value R0 by the cooling control. (Step 40)
4,409). By this cooling, the room temperature Tr decreases, the room humidity Rr increases, and is adjusted to the room humidity setting target value R0. That is, in this case, the control device 3-2
, The controlled room 2 is humidified until Rr = R0.

[When in the region J] It is assumed that the state point of the controlled room 2 is at point P28 in the region J. That is, when the room temperature Tr is the room temperature setting target value T0 and the room humidity Rr is the room humidity setting target value R0 (point P30).
It is assumed that a region below the absolute humidity value Ar (T0, R0) = Ar3 and having a relative humidity of 100% or less is a region J, and a state point of the controlled room 2 is located at a point P28 in the region J.

In this case, the control device 3-2 controls the air conditioner 1 so that the state point P28 is located at the intersection P30 of the indoor temperature set target value T0 and the indoor humidity set target value R0 by the humidification / cooling control. The intake air is humidified using the humidifier 1-3 until it reaches the absolute humidity Ar3 (point P29), and is cooled to the room temperature set target value T0 using the cooling coil 1-1 (steps 404 and 410). ).

Note that the state point of the controlled room 2 is P
If it is at point 31, humidification control to the absolute humidity value Ar3 is performed. When it is at the point P32, humidification control to the absolute humidity value Ar3 and heating control to the indoor temperature setting target value T0 are performed (humidification / heating control).

In the second embodiment, since the relative humidity setting upper limit value R1 is provided, further energy saving can be achieved as compared with the first embodiment. That is, it is assumed that the state point of the controlled room 2 is at P18 in the psychrometric chart of FIG. 3 and the relative humidity setting upper limit value R1 is not provided. In this case, the P18 point is set to the relative humidity setting target value R0 by the heating control.
, The room temperature Tr does not fall within the allowable temperature range T0 to T1. For this reason, in Embodiment 1, the point P18 is located at the point P35 by the cooling / heating control. On the other hand, in the second embodiment, since the relative humidity setting upper limit value R1 is provided, the point P18 may be located on the line L2 of this R1 only by heating control, thereby saving energy.

In the first and second embodiments, the room temperature Tr and the room humidity (relative humidity) Rr are measured.
Although the current absolute humidity Ar in the controlled room 2 is obtained based on the measured room temperature Tr and room humidity Rr, the absolute humidity sensor is used as the humidity sensor 7 instead of the relative humidity sensor. Ar may be directly obtained. In this case, the relative humidity Rr in the controlled room 2 can be obtained based on the room temperature Tr and the absolute humidity Ar.

In the first and second embodiments, the air conditioner 1 having the cooling coil 1-1 and the heating coil 1-2
Has been described as an example of application to a constant-temperature and constant-humidity air-conditioning control system using the same. However, a constant-temperature and constant-humidity air-conditioning control system in which an air conditioner having no heating coil 1-2 and a reheater are combined can be similarly applied.

[0047]

As is apparent from the above description, according to the present invention, in the first invention, when the current relative humidity is higher than the set relative humidity and the room temperature is raised within the allowable temperature range, the relative humidity is increased. In the case where the temperature is adjusted to the relative humidity set value, heating is controlled and dehumidification is achieved, so large energy saving is achieved as compared with the conventional cooling and heating control method, and energy consumption when dehumidifying is suppressed. Thus, the cost of air conditioning can be reduced. In the second invention, when the absolute humidity is high and the cooling / heating control must be performed, the temperature setting upper limit value and the relative humidity setting value are used instead of the intersection of the temperature setting target value and the relative humidity setting value as in the related art. Cooling and heating control is performed so that the state point is located at the intersection with the value, so that the set temperature for cooling control can be increased, energy saving is achieved, and energy consumption during dehumidification is suppressed, and air conditioning is performed. The cost can be reduced. In the third invention, if the current relative humidity is higher than the relative humidity setting upper limit and the room temperature is raised within the allowable temperature range, the relative humidity can be made to match between the relative humidity setting upper limit and the relative humidity setting target value. In such a case, since the heating is controlled and the dehumidification is achieved, the range in which the heating and dehumidification can be further expanded as compared with the first invention, and further energy saving is achieved. In the fourth invention,
When absolute humidity is high and cooling / heating control must be performed, instead of the intersection of the temperature setting target value and the relative humidity setting value as in the past, the intersection of the temperature setting upper limit value and the relative humidity setting upper limit value Cooling and heating control is performed so that the state point is located at a higher temperature, so that the set temperature during cooling control can be increased, energy saving is achieved, energy consumption during dehumidification is suppressed, and air conditioning costs are reduced. You can plan.

[Brief description of the drawings]

FIG. 1 is an air conditioning control method according to the present invention (first embodiment).
FIG. 4 is an air line diagram for explaining an operation of a constant temperature / humidity air conditioning control system to which is applied.

FIG. 2 is a flowchart showing a specific processing operation performed by a control device in the constant temperature / humidity air conditioning control system.

FIG. 3 is an air conditioning control method according to the present invention (Embodiment 2);
FIG. 4 is an air line diagram for explaining an operation of a constant temperature / humidity air conditioning control system to which is applied.

FIG. 4 is a flowchart showing a specific processing operation performed by a control device in the constant temperature / humidity air conditioning control system.

FIG. 5 is a diagram showing a main part of a constant temperature / humidity air conditioning control system according to the related art and the present invention.

FIG. 6 is an air line diagram for explaining the operation of the conventional constant temperature / humidity air conditioning control system.

[Explanation of symbols]

1. Air conditioner 1-1: Heat exchanger for cooling (cooling coil),
1-2: heating heat exchanger (heating coil), 1-3: humidifier, 2 ... controlled room (air conditioning control area), 3-1 and 3-2
... Control device, 4,5 ... Control valve, 6 ... Temperature sensor, 7 ... Humidity sensor (relative humidity sensor).

Claims (4)

[Claims] 1. An air-conditioning control area having a relative humidity controlled to a predetermined relative humidity set value, and an indoor temperature of the air-conditioning control area controlled within an allowable temperature range defined by a temperature setting target value and a temperature setting upper limit value. An air-conditioning control method that determines a current state point of the air-conditioning control area determined by the room temperature and the absolute humidity in the psychrometric chart, wherein the state point is such that the room temperature is the target temperature setting value and the relative humidity is the relative humidity. When the room temperature is equal to or higher than the first absolute humidity value when the humidity is the set value, the room temperature is equal to or higher than the second absolute humidity value when the relative humidity is equal to the relative humidity set value, and the relative humidity is equal to or lower than the second absolute humidity value. In the case where the temperature is within the range of 100% or less and exceeds the relative humidity set value, heating of the indoor temperature of the air conditioning control area is controlled so that this state point is located on the line of the relative humidity set value. An air-conditioning control method comprising: 2. Controlling the relative humidity of the air-conditioning control area to a predetermined relative humidity set value, and controlling the room temperature of the air-conditioning control area within an allowable temperature range defined by a temperature setting target value and a temperature setting upper limit value. An air-conditioning control method that determines a current state point of the air-conditioning control area determined by the room temperature and the absolute humidity in the psychrometric chart, and the state point is such that the room temperature is the temperature setting upper limit and the relative humidity is the relative humidity. If the absolute humidity is higher than the absolute humidity when the humidity is the set value and the relative humidity is 100% or less, the air conditioning control is performed so that this state point is located at the intersection of the temperature set upper limit and the relative humidity set value. An air-conditioning control method characterized by controlling the cooling and heating of the indoor temperature of an area. 3. The relative humidity of the air-conditioning control area is controlled within an allowable relative humidity range defined by a relative humidity setting target value and a relative humidity setting upper limit, and the indoor temperature of the air-conditioning control area is set to a temperature setting target value. In an air-conditioning control method for controlling the temperature within an allowable temperature range defined by a temperature setting upper limit value, a current state point of an air-conditioning control area defined by an indoor temperature and an absolute humidity in an air chart is obtained, When the temperature is the temperature setting target value and the relative humidity is the first absolute humidity value when the relative humidity is the relative humidity setting target value, the room temperature is the temperature setting target value and the relative humidity is the relative humidity setting upper limit. The second when the value
If the temperature is below the temperature setting target value when the absolute humidity value is not more than the absolute humidity value and the relative humidity is not more than 100%, the indoor state of the air-conditioning control area is set so that this state point is located on the line of the temperature setting target value. Controlling the temperature by heating, wherein the state point exceeds the second absolute humidity value when the room temperature is the temperature setting target value and the relative humidity is the relative humidity setting upper limit value, and the room temperature is the temperature setting upper limit. If the relative humidity is below the third absolute humidity value when the relative humidity is the relative humidity set upper limit and the relative humidity is 100% or less and exceeds the relative humidity set upper limit, this state An air-conditioning control method, wherein the heating of the room temperature in the air-conditioning control area is controlled so that the point is located on the line of the relative humidity setting upper limit value. 4. The method of controlling the relative humidity of the air-conditioning control area within an allowable relative humidity range defined by a relative humidity setting target value and a relative humidity setting upper limit value, and setting the indoor temperature of the air-conditioning control area to a temperature setting target value. In an air-conditioning control method for controlling the temperature within an allowable temperature range defined by a temperature setting upper limit value, a current state point of an air-conditioning control area defined by an indoor temperature and an absolute humidity in an air chart is obtained, If the temperature is above the temperature setting upper limit value and the relative humidity exceeds the absolute humidity value when the relative humidity setting value is the upper limit value and the relative humidity is in an area of 100% or less, the state point is set to the temperature setting upper limit value. And controlling the cooling and heating of the room temperature in the air-conditioning control area so that the room temperature is located at the intersection of the upper limit value and the relative humidity setting value.