JP2004308957A - Method and device for evaluating air-conditioning control state - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To rapidly grasp the good or bad of an air-conditioning control state in a controlled area in an air volume varying air conditioning system such as a VAV air conditioning system. <P>SOLUTION: The static pressure state of the fan of an air conditioner is determined by using the damper opening θ of a VAV unit and a temperature deviation Δt between an indoor temperature and a set temperature (static pressure over/static pressure appropriate/static pressure short). An air volume ratio α is obtained by using the blown amount Q of air supply from the VAV unit, and the air blow state (air blow amount over/air blow amount appropriate/air blow amount short) of the fan of the air conditioner by using the air volume ratio α and the temperature deviation Δt. Based on this determined results, the air volume ratio α and the damper opening θ are plotted on a two-dimensional graph G1 in which the damper opening θ is taken on an abscissa and the air volume ratio α is taken on an ordinate. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method and an apparatus for evaluating an air conditioning control state in a VAV (variable air volume control) air conditioning system or the like.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, for example, in a VAV air-conditioning system, a supply air supply amount adjustment unit (VAV unit) is provided in an air supply duct from an air conditioner to a controlled area, and an opening degree θ of a damper of the VAV unit is set to a room in the controlled area. Control is performed according to the temperature deviation between the temperature tpv and the set temperature tsp to adjust the amount Q of supply air to the controlled area (for example, see Patent Documents 1 and 2).
[0003]
The VAV air-conditioning system is provided with a monitoring panel, on which the current room temperature tpv and the set temperature tsp of the controlled area, the amount of supply air Q to the controlled area, and the like are numerically displayed. Thus, the current air-conditioning control state of the controlled area is notified to the administrator.
[0004]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2000-304333 [Patent Document 2]
JP 2000-357012 A
[Problems to be solved by the invention]
However, in the above-described VAV air-conditioning system, since the current room temperature tpv and the set temperature tsp of the controlled area, the amount of supply air Q to the controlled area, and the like are only displayed numerically on the monitoring panel, the management is not performed. The user cannot quickly grasp the quality of the current air-conditioning control state for the controlled area, and the determination is delayed.
[0006]
The present invention has been made to solve such a problem, and an object of the present invention is to provide a variable air-conditioning air-conditioning system such as a VAV air-conditioning system in which the current air-conditioning control state of a controlled area can be quickly and properly determined. An object of the present invention is to provide a method and an apparatus for evaluating an air-conditioning control state that enable grasping.
[0007]
[Means for Solving the Problems]
In order to achieve such an object, the present invention provides an air conditioner, a damper provided in an air supply duct from the air conditioner to a controlled area, and a temperature deviation between a room temperature and a set temperature of the controlled area. Control means for controlling the opening degree of the damper in accordance with the air pressure and adjusting the amount of air supply to the controlled area. The static pressure state of the air supply from the air conditioner to the controlled area is determined based on the temperature deviation between the air conditioner and the controlled air temperature, the amount of air supply to the controlled area, the room temperature of the controlled area, and the set temperature. Is determined based on the temperature deviation of the air supply from the air conditioner to the controlled area.
[0008]
According to the present invention, based on the damper opening (θ), the temperature deviation (Δt) between the room temperature (tpv) of the controlled area and the set temperature (tsp), the air supply from the air conditioner to the controlled area is reduced. The pressure state (for example, excessive static pressure / appropriate static pressure / insufficient static pressure) is determined, and the amount (Q) of supply air to the controlled area, the room temperature (tpv) of the controlled area, and the set temperature ( Based on the temperature deviation (Δt) from (tsp), the state of the supply amount of air supply from the air conditioner to the controlled area (for example, excessive air supply / appropriate air supply / insufficient air supply) is determined.
[0009]
By displaying the “static pressure state of air supply to the controlled area” and the “state of air supply amount to the controlled area” determined in this way, for example, on a two-dimensional graph, By displaying the result on a two-dimensional graph, it is possible to quickly grasp the quality of the current air conditioning control state for the controlled area.
[0010]
Normally, there are a plurality of controlled areas, and a damper and a supply air blowing amount adjusting means are provided for each of the plurality of controlled areas. In this case, the determination of the static pressure state of the supply air and the determination of the supply air supply state are performed for each controlled area. The “static pressure state of air supply to the controlled area” and the “state of air supply amount to the controlled area” for each controlled area determined in this way are displayed on, for example, a two-dimensional graph. This makes it possible to quickly grasp the quality of the current air conditioning control state for each controlled area.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is an instrumentation diagram showing an example of a VAV air-conditioning system used for implementing an air-conditioning control state evaluation method according to the present invention.
In FIG. 1, reference numeral 1 denotes an air conditioner, which includes a cooling coil 3 to which cold water CW is supplied via a control valve 2, a heating coil 5 to which hot water HW is supplied via a control valve 4, and a fan 6. .
[0012]
Reference numeral 7 denotes a control device for controlling the operations of the control valves 2 and 4 and the fan 6, and reference numeral 15 denotes a display device connected to the control device 7. In this VAV air conditioning system, air supply from the air conditioner 1 that is blown out of the fan 6 through the cooling coil 3 and the heating coil 5 is supplied to the controlled areas 9-1 to 9-n through the air supply duct 8. You. The air supply duct 8 is provided with an air supply temperature sensor TS for detecting the temperature of air supply from the air conditioner 1. The supply air temperature detected by the supply air temperature sensor TS is sent to the control device 7.
[0013]
In the controlled areas 9-1 to 9-n, temperature sensors T1 to Tn for detecting the indoor temperature are provided for each area, and the indoor temperatures tpv1 to tpvn detected by the temperature sensors T1 to Tn are locally detected. It is provided to each of the provided VAV control units 10-1 to 10-n.
[0014]
The VAV control unit 10 (10-1 to 10-n) sends the temperature deviation Δt (Δt1 to Δtn) between the room temperature tpv (tpv1 to tpvn) and the set temperature tsp (tsp1 to tspn) and is sent from the control device 7. The required air volume to the controlled area 9 (9-1 to 9-n) is calculated based on the incoming air supply temperature, and the VAV unit 11 (11-1 to 11-n) is operated so as to secure the required air volume. The opening degrees θ (θ1 to θn) of the dampers 12 (12-1 to 12-n) are controlled while observing the actual air volume Q (Q1 to Qn) detected by the wind speed sensors 13 (13-1 to 13-n). .
[0015]
Each of the VAV units 11 (11-1 to 11-n) is provided with a position switch (position meter or the like) 14 (14-1 to 14-n) indicating an opening, and a damper opening θ (θ1 to θn). ) Is fed back to the VAV control unit 10 (10-1 to 10-n). Note that an opening instruction value of the opening control may be used instead of the position switch 14 indicating the opening. Further, the actual air volume Q (Q1 to Qn) detected by the wind speed sensor 13 (13-1 to 13-n) is used as a VAV control value as an amount of air supply to the controlled area 9 (9-1 to 9-n). Unit 10 (10-1 to 10-n).
[0016]
FIG. 2 is a functional block diagram showing functions unique to the present embodiment that the VAV control unit 10 has. The VAV control unit 10 includes an air volume ratio calculation unit 10A, a fan static pressure state determination unit 10B, and a fan air volume state determination unit 10C. In the present embodiment, the air volume ratio calculation unit 10A, the fan static pressure state determination unit 10B, and the fan air volume state determination unit 10C constitute evaluation means for evaluating the current air conditioning control state for the controlled area 9. Have been. The VAV control unit 10 is realized by hardware including a processor and a storage device, and a program that realizes various functions as a VAV control unit in cooperation with the hardware.
[0017]
(Air volume ratio calculation unit)
The air volume ratio calculation unit 10A receives the current air volume Q of the supply air from the VAV unit 11 to the controlled area 9 and calculates the following from a predetermined air volume lower limit value Qmin and a predetermined air volume upper limit value Qmax. The air volume ratio α is calculated according to the equation (1).
α = [(Q−Qmin) / (Qmax−Qmin)] × 100 (%) (1)
[0018]
[Fan static pressure state determination unit]
The fan static pressure state determination unit 10B receives the damper opening θ from the VAV unit 11, the room temperature tpv from the temperature sensor T, and the set temperature tsp, and receives the static pressure state of the fan 6 (fan static pressure state: air conditioner). 1 to the controlled area 9).
[0019]
In the present embodiment, an allowable error ε is determined for the temperature deviation Δt (Δt = | tpv−tsp |) between the room temperature tpv and the set temperature tsp, and the maximum opening θmax ( In this example, 100%) and the minimum opening θmin (85% in this example) are determined, and a case where the damper opening θ is θ <θmin and Δt> ε is determined as “excessive static pressure”. When the damper opening θ is θmin ≦ θ ≦ θmax and Δt ≦ ε, it is determined that “static pressure is appropriate”, and when the damper opening θ is θ> θmax and Δt> ε, “static pressure is insufficient”. Is determined.
[0020]
In the present embodiment, the maximum opening degree θmax = 100% refers to a state in which the damper 12 is not in the fully opened state, but is in a maximum opening degree set slightly before the fully opened state.
[0021]
[Fan blast volume state determination unit]
The fan air volume state determination unit 10C receives the air supply volume Q from the VAV unit 11, the room temperature tpv from the temperature sensor T, and the set temperature tsp, and receives the air volume state of the fan 6 (fan air volume state: The state of the supply amount of air supply from the air conditioner 1 to the controlled area 9 is determined.
[0022]
In the present embodiment, an allowable error ε is determined for the temperature deviation Δt (Δt = | tpv−tsp |) between the room temperature tpv and the set temperature tsp, and the maximum air volume ratio αmax (this In the example, 100%) and the minimum air volume ratio αmin (0% in this example) are determined, and when the air volume ratio α is α <αmin and Δt> ε, it is determined that “the air volume is excessive”. When the air volume ratio α is αmin ≦ α ≦ αmax and Δt ≦ ε, it is determined that the air volume is appropriate, and when the air volume ratio α is α> αmax and Δt> ε, it is determined that the air volume is insufficient. I do.
[0023]
Note that, in the present embodiment, that the air volume ratio α is α <0% means that the current air supply amount Q is Q <Qmin, and that the air volume ratio α is α> 100%. , Means that the current blowing amount Q is Q> Qmax.
[0024]
FIG. 3 is a functional block diagram showing functions unique to the present embodiment that the control device 7 has. The control device 7 includes an air-conditioning control state plotting unit 7A. The air-conditioning control state plotting section 7A receives the damper opening degree θ, the air volume ratio α, the fan static pressure state and the fan air flow state sent from the VAV control unit 10 as inputs, and displays the damper opening state in a two-dimensional graph G1 shown in FIG. A point determined by the degree θ and the air volume ratio α is plotted as a state point of the current air-conditioning control state for the controlled area 9. The control device 7 is realized by hardware including a processor and a storage device, and a program that realizes various functions as a control device in cooperation with the hardware.
[0025]
[2D graph]
The two-dimensional graph G1 is an online evaluation graph displayed on the screen of the display device 15, where the damper opening θ is a vertical axis (or horizontal axis), and the air volume ratio α is a horizontal axis (or vertical axis). . The range where the damper opening θ is 0% ≦ θ <85% indicates an excessive static pressure range, the range where 85% ≦ θ ≦ 100% indicates an appropriate static pressure range, and 100% <θ <upper limit% indicates insufficient static pressure. Indicates the area. When the air volume ratio α is in the range of lower limit% <α <0%, it indicates an excess air volume region, 0% ≦ α ≦ 100% indicates an appropriate air volume region, and 100% <α <upper limit% indicates an insufficient air volume region. . In the present embodiment, the two-dimensional graph G1 is divided into a static pressure insufficiency area, an appropriate static pressure area, an excessive static pressure area and an excessive air flow rate area, an appropriate air flow rate area, and an insufficient air quantity area in the horizontal axis. It is divided into seven areas A, B, C, D, E, F and G.
[0026]
In the two-dimensional graph G1, a region A indicates a region where both the static pressure and the air flow are appropriate, and a region B indicates a region where the static pressure is insufficient but the air flow is appropriate. The area C indicates an area where the static pressure is excessive but the air flow is appropriate, and the area D indicates an area where the static pressure is appropriate or excessive and the air flow is insufficient. A region E indicates a region where the static pressure is appropriate or excessive, and the air flow rate is excessive. An area F indicates an area where both the static pressure and the air flow rate are insufficient. A region G indicates a region where the static pressure is insufficient and the air flow rate is excessive. The regions D and E may be divided into two regions by an appropriate static pressure region and an excessive static pressure region.
[0027]
Hereinafter, for simplicity of description, taking a single controlled area 9-1 as an example, a plot of a state point of the current air-conditioning control state on the two-dimensional graph G1 by the control device 7 (a plot of an evaluation result) will be described. .
[0028]
[Plot to region A]
FIG. 5 is a plot of state points on the two-dimensional graph G1 when the air volume ratio α1 calculated by the VAV control unit 10-1 is 50%, the damper opening θ1 is 95%, and the temperature deviation Δt1 is Δt1 ≦ ε. An example is shown. In this case, the VAV control unit 10-1 sends “appropriate static pressure” as the fan static pressure state and “appropriate air flow” as the fan air flow rate state to the control apparatus 7, so that the control apparatus 7 outputs the two-dimensional graph G1. A state point P1 determined by the damper opening θ1 and the air volume ratio α1 is plotted in the area A of FIG.
[0029]
[Plot to region B]
FIG. 6 is a state point on the two-dimensional graph G1 when the air volume ratio α1 calculated by the VAV control unit 10-1 is 50%, the damper opening θ1 is θ1> 100%, and the temperature deviation Δt1 is Δt1> ε. 2 shows a plot example. In this case, the VAV control unit 10-1 sends “insufficient static pressure” as the fan static pressure state to the control device 7 and “appropriate air flow” as the fan air flow amount status. The state point P1 determined by the damper opening degree θ1 and the air volume ratio α1 is plotted in the region B.
[0030]
[Plot to area C]
FIG. 7 is a plot of state points on the two-dimensional graph G1 when the air volume ratio α1 calculated by the VAV control unit 10-1 is 50%, the damper opening θ1 is 80%, and the temperature deviation Δt1 is Δt1> ε. An example is shown. In this case, the VAV control unit 10-1 sends "excessive static pressure" as the fan static pressure state to the control device 7 and "appropriate air flow" as the fan air flow amount state. A state point P1 determined by the damper opening θ1 and the air volume ratio α1 is plotted in the region C of FIG.
[0031]
[Plot to area D]
FIG. 8 is a state point on the two-dimensional graph G1 when the air volume ratio α1 calculated by the VAV control unit 10-1 is α1> 100%, the damper opening θ1 is 92%, and the temperature deviation Δt1 is Δt1> ε. 2 shows a plot example. In this case, the VAV control unit 10-1 sends “appropriate static pressure” as the fan static pressure state to the control device 7 and “insufficient air flow” as the fan air flow amount state. A state point P1 determined by the damper opening θ1 and the air volume ratio α1 is plotted in the region D of FIG. Such a phenomenon appears when the indoor air-conditioning load is excessively large, or when the difference between the blown air temperatures (the difference between the supply air temperature and the indoor temperature) is too small.
[0032]
[Plot to area E]
FIG. 9 is a state point on the two-dimensional graph G1 when the air volume ratio α1 calculated by the VAV control unit 10-1 is α1 <0%, the damper opening θ1 is 93%, and the temperature deviation Δt1 is Δt1> ε. 2 shows a plot example. In this case, the VAV control unit 10-1 sends “appropriate static pressure” as the fan static pressure state and “excess air flow” as the fan air volume state to the control device 7, so the control device 7 transmits the two-dimensional graph G1. The state point P1 determined by the damper opening θ1 and the air volume ratio α1 is plotted in the region E of FIG. Such a phenomenon appears when the indoor air-conditioning load is too small, or when the temperature difference between the blowers is too large.
[0033]
[Plot to area F]
FIG. 10 shows a two-dimensional graph G1 when the air volume ratio α1 calculated by the VAV control unit 10-1 is α1> 100%, the damper opening θ1 is θ1> 100%, and the temperature deviation Δt1 is Δt1> ε. 7 shows a plot example of state points. In this case, the VAV control unit 10-1 sends “static insufficiency” as the fan static pressure state and “insufficient air flow” as the fan air volume state to the controller 7, so that the controller 7 generates the two-dimensional graph G1. A state point P1 determined by the damper opening degree θ1 and the air volume ratio α1 is plotted in the region F. Such a phenomenon appears when the indoor air-conditioning load exceeds the design condition, or when the difference in air supply temperature with respect to the current load is too small due to supply air temperature restriction.
[0034]
[Plot to region G]
FIG. 11 shows a two-dimensional graph G1 when the air volume ratio α1 calculated by the VAV control unit 10-1 is α1 <0%, the damper opening θ1 is θ1> 100%, and the temperature deviation Δt1 is Δt1> ε. 7 shows a plot example of state points. In this case, the VAV control unit 10-1 sends “static insufficiency” as the fan static pressure state and “excessive air flow” as the fan air volume state to the controller 7, so that the controller 7 transmits the two-dimensional graph G1. The state point P1 determined by the damper opening θ1 and the air flow ratio α1 is plotted in the region G of FIG. If the VAV air-conditioning system is normal, such a phenomenon does not appear, which means that the VAV air-conditioning system in which this phenomenon appears has failed.
[0035]
The plotting of the state points of the current air-conditioning control state on the two-dimensional graph G1 by the control device 7 has been described using the controlled area 9-1 as an example.
In this VAV air-conditioning system, there are a plurality of controlled areas 9, and a VAV unit 11 and a VAV control unit 10 are provided for each of the plurality of controlled areas 9. Similarly to the VAV control unit 10-1, the VAV control units 10-2 (not shown) to 10-n also transmit the damper opening θ, the air volume ratio α, the fan static pressure state, and the fan air flow amount state to the control device 7. send.
The control device 7 controls the controlled area 9-2 (see FIG. 3) based on the damper opening θ, the air volume ratio α, the fan static pressure state, and the fan air volume state sent from the VAV control units 10-2 to 10-n. As for the controlled area 9-1, the state points of the current air-conditioning control state are plotted for the not-shown areas 9-n.
[0036]
FIGS. 12, 13, and 14 show examples of plots of the state points of the current air-conditioning control state with respect to the controlled areas 9-1 to 9-n.
In the example of FIG. 12, all the state points of the current air-conditioning control state for the controlled areas 9-1 to 9-n fall within the area A, and from this display state, all are suitable for both the static pressure and the air flow. You can see at a glance. Although the air volume ratio α varies somewhat, the damper opening degrees θ are all close to 100%. Such a state is an ideal state in which the load patterns of the controlled areas 9-1 to 9-n match well, and the number is extremely small.
[0037]
In the example of FIG. 13, the state points of the current air-conditioning control state for the controlled areas 9-1 to 9-n are dispersed in the area A and the area C. That is, there is a mixture of one where the static pressure and the amount of air are appropriate, and another one where the amount of air is appropriate but the static pressure is excessive. Such a state is a state often seen in a general VAV air conditioning system.
[0038]
In the example of FIG. 14, the state points of the current air-conditioning control state for the controlled areas 9-1 to 9-n are distributed to the area A and the area C, one of which is in the area D, and the other is in the area E. ing. That is, the static pressure and the air volume are appropriate, the air volume is appropriate but the static pressure is excessive, the static pressure is appropriate but the air volume is insufficient, Some airflow is excessive and some airflow is excessive. Such a state is often seen when the controlled areas 9-1 to 9-n having different load patterns are combined into one VAV air conditioning system.
[0039]
As described above, according to the present embodiment, the state points plotted on the two-dimensional graph G1 enable quick grasp of the quality of the current air conditioning control state for the controlled areas 9-1 to 9-n. In addition, the efficiency of operation management, high quality, and labor saving can be achieved.
[0040]
Although FIG. 1 shows a VAV air-conditioning system having a plurality of controlled areas 9, it goes without saying that the present invention can be similarly applied to a case where there is one controlled area 9.
In the above-described embodiment, only the state points are plotted in the regions A to G. However, the regions may be colored and displayed together with the plot of the state points. Alternatively, the state point may not be plotted, and only that area may be colored.
[0041]
【The invention's effect】
As is apparent from the above description, according to the present invention, the static pressure state of the air supply from the air conditioner to the controlled area is determined based on the damper opening and the temperature deviation between the room temperature and the set temperature of the controlled area. In addition, the state of the supply amount of air supply from the air conditioner to the controlled area is determined based on the amount of air supply to the controlled area and the temperature difference between the room temperature and the set temperature of the controlled area. Since the determination is made, the “static pressure state of air supply to the controlled area” and the “state of air supply amount to the controlled area” are displayed on, for example, a two-dimensional graph, so that the controlled It is possible to quickly grasp the quality of the current air-conditioning control state for the area, and it is possible to achieve more efficient operation management, higher quality, and labor saving.
[Brief description of the drawings]
FIG. 1 is an instrumentation diagram showing an example of a VAV air-conditioning system used for implementing an air-conditioning control state evaluation method according to the present invention.
FIG. 2 is a functional block diagram showing unique functions of a VAV control unit in the VAV air conditioning system.
FIG. 3 is a functional block diagram showing unique functions of a control device in the VAV air conditioning system.
FIG. 4 is a diagram showing a two-dimensional graph (on-line evaluation graph) displayed on a screen of a display device in the VAV air-conditioning system.
FIG. 5 is a diagram illustrating a plot of a state point of a current air-conditioning control state for a controlled area on a two-dimensional graph.
FIG. 6 is a diagram illustrating a plot of a state point of a current air-conditioning control state for a controlled area on a two-dimensional graph.
FIG. 7 is a diagram illustrating a plot of a state point of a current air-conditioning control state for a controlled area on a two-dimensional graph.
FIG. 8 is a diagram illustrating a plot of a state point of a current air-conditioning control state for a controlled area on a two-dimensional graph.
FIG. 9 is a diagram illustrating a plot of a state point of a current air-conditioning control state for a controlled area on a two-dimensional graph.
FIG. 10 is a diagram illustrating a plot of a state point of a current air-conditioning control state for a controlled area on a two-dimensional graph.
FIG. 11 is a diagram illustrating a plot of a state point of a current air-conditioning control state for a controlled area on a two-dimensional graph.
FIG. 12 is a diagram illustrating a plot of state points of a current air-conditioning control state for a plurality of controlled areas on a two-dimensional graph.
FIG. 13 is a diagram illustrating a plot of state points of a current air conditioning control state for a plurality of controlled areas on a two-dimensional graph.
FIG. 14 is a diagram illustrating a plot of state points of a current air conditioning control state for a plurality of controlled areas on a two-dimensional graph.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Air conditioner, 2, 4 ... Control valve, 3 ... Cooling coil, 5 ... Heating coil, 6 ... Fan, 7 ... Control device, 8 ... Air supply duct, 9 (9-1 to 9-n) ... Controlled Area, 10 (10-1 to 10-n) VAV control unit, 10A air volume ratio calculation unit, 10B fan static pressure state determination unit, 10C fan air flow amount state determination unit, 11 (11-1 to 11-) n) VAV unit, 12 (12-1 to 12-n) damper, 13 (13-1 to 13-n) wind speed sensor, 14 (14-1 to 14-n) position switch indicating opening (Position meter, etc.), T (T1 to Tn): temperature sensor, TS: supply air temperature sensor.

Claims (6)

An air conditioner, a damper provided in an air supply duct from the air conditioner to a controlled area, and controlling an opening degree of the damper according to a temperature deviation between a room temperature and a set temperature of the controlled area, A system comprising: an air supply amount adjustment unit for adjusting an air supply amount to the controlled area, wherein the damper opening degree, the air supply amount to the controlled area, and a room in the controlled area. An air conditioning control state evaluation method for evaluating a current air conditioning control state for the controlled area based on a temperature deviation between a temperature and a set temperature,
A first step of determining a static pressure state of air supply from the air conditioner to the controlled area based on the damper opening and a temperature difference between a room temperature and a set temperature of the controlled area;
Judging the state of the supply amount of air supply from the air conditioner to the controlled area based on the amount of air supply to the controlled area and the temperature deviation between the room temperature and the set temperature of the controlled area; A method for evaluating an air conditioning control state, comprising: two steps. The method for evaluating an air-conditioning control state according to claim 1,
A second step of displaying, on a two-dimensional graph, a static pressure state of air supply to the controlled area determined in the first step and a state of a supply amount of air supply to the controlled area determined in the second step; An air conditioning control state evaluation method, comprising three steps. The method for evaluating an air-conditioning control state according to claim 1 or 2,
There are a plurality of the controlled areas,
The damper and the supply air blowing amount adjusting means are provided for each of the plurality of controlled areas,
A method for evaluating an air-conditioning control state, comprising: determining a static pressure state of supply air in the first step and determining a supply air supply state in the second step for each controlled area. An air conditioner, a damper provided in an air supply duct from the air conditioner to a controlled area, and controlling an opening degree of the damper according to a temperature deviation between a room temperature and a set temperature of the controlled area, Supply air blowoff amount adjusting means for adjusting the blowout amount of air supply to the controlled area, the damper opening, the blowout amount of air supply to the controlled area, the room temperature and the set temperature of the controlled area, Evaluation means for evaluating a current air conditioning control state for the controlled area based on the temperature deviation of the air conditioning control state,
The evaluation means,
A static pressure state determining means for determining a static pressure state of air supply from the air conditioner to the controlled area based on a temperature difference between the damper opening degree and the set temperature of the room temperature of the controlled area,
Determining a state of a supply amount of air from the air conditioner to the controlled area based on an amount of air supply to the controlled area and a temperature difference between a room temperature and a set temperature of the controlled area; An air conditioning control state evaluation device, comprising: an air supply amount state determination unit. The evaluation device for an air-conditioning control state according to claim 4,
The static pressure state of the supply air to the controlled area determined by the static pressure state determination means and the supply air supply state to the controlled area determined by the supply air supply amount state determination means An air conditioning control state evaluation device, comprising: means for displaying on a two-dimensional graph. The evaluation device for an air-conditioning control state according to claim 4 or 5,
There are a plurality of the controlled areas,
An evaluation of an air-conditioning control state, characterized in that the plurality of controlled areas are provided with the damper, the supply air blowing amount adjusting means, the static pressure state determining means and the supply air supply state determining means. apparatus.

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