JP2013137140A - Air volume control system and air volume control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress fan power loss regardless of whichever required opening degrees are combined.SOLUTION: An air volume control system includes: an air conditioner; a variable air volume unit for controlling an air volume of supply air; a plurality of outlet damper units each provided with an outlet damper; a requested air volume determining part (1230) for determining a requested air volume of each outlet according to an air volume setting request from a dweller; an outlet damper opening degree determining part (1232, 1233) for determining an opening degree of the outlet damper of the each outlet by comprehensively considering the requested air volume of the each outlet such that the opening degree approaches a predetermined upper limit opening degree compared to the case that the opening degree of the outlet damper of the each outlet is independently determined based on the requested air volume of the each outlet; an outlet damper controlling part (1235) for controlling the each outlet damper; a total requested air volume calculating part for calculating a total value of the requested air volume of the each outlet; a supply air volume controlling part for controlling a rotation rate of a fan in the air conditioner such that the supply air volume supplied from the air conditioner matches the total value of the requested air volume.

Description

  The present invention relates to an air volume control system and an air volume control method for controlling the air volume of supply air supplied from an air conditioner to a plurality of supply air outlets for each of the air outlets.

  When responding to an environmental change request for each air outlet or each set of air outlets using a VAV (Variable Air Volume) air conditioning system, a plurality of air dampers are provided between the VAV and the air outlets. Is changed according to the degree of the environmental change request (see, for example, Patent Document 1).

JP 2005-127636 A

  In an air conditioning system in which a blower damper is provided between the VAV and the blower outlet, each blower damper is controlled independently without cooperation, so that each blower damper is higher than the lower limit of the blower damper opening. When a request for a smaller opening (hereinafter, intermediate opening) is received, there is a problem that fan power loss occurs due to pressure loss.

  An increase in fan power loss due to pressure loss will be described with reference to FIGS. 7 (A) and 7 (B). FIG. 7A shows the relationship between the air volume and the static pressure when the opening degree of the blowing damper is set to the upper limit opening degree. A curve 100 in FIG. 7A indicates the blower damper upper limit opening degree, a curve 101 indicates the fan rotation speed when the air volume Q flows at the blow damper upper limit opening degree, and 102 flows the air volume Q at the blow damper upper limit opening degree. The operating point is shown. Reference numeral 103 denotes the product of the static pressure and the air volume, which is a value corresponding to the amount of power consumed by the fan when the air volume Q flows at the upper limit of the blow-out damper.

  FIG. 7B shows the relationship between the air volume and the static pressure when the opening degree of the blowing damper is set to the intermediate opening degree. In FIG. 7B, a curve 104 indicates the blow damper intermediate opening, a curve 105 indicates the fan rotation speed when the air volume Q flows at the blow damper intermediate opening, and 106 flows the air volume Q at the blow damper intermediate opening. The operating point is shown. Reference numeral 107 denotes a value corresponding to the amount of power consumed by the fan in the case where the air volume Q flows at the intermediate opening degree of the blow damper.

  As is clear when comparing the case of FIG. 7 (A) where the opening degree of the blowing damper is the upper limit opening degree and the case of FIG. 7 (B) where the opening degree of the blowing damper is the intermediate opening degree, the same air volume Q is obtained. Even if it is desired to flow, since the fan rotation speed is higher when the blowout damper is at the intermediate opening, the power consumption of the fan proportional to the product of the static pressure and the air volume increases.

  The present invention has been made in order to solve the above-described problems, and the air volume control capable of minimizing the fan power loss due to the pressure loss regardless of the resident air volume setting request for each zone. It is an object to provide a system and an air volume control method.

  An air volume control system according to the present invention includes an air conditioner including a fan for sending out air supply, a variable air volume unit provided in a supply air system supplied from the air conditioner, and an air supply amount sent through the variable air volume unit. A plurality of blower damper units provided with blowout dampers that are provided for each blower outlet or each set of a plurality of blower outlets to control the air volume of the supply air, and each of the air supply outlets according to the air volume setting request from the resident Rather than the case where the required air volume determining means for determining the required air volume and the opening degree of the outlet damper of each air outlet are determined independently from the required air volume of each air outlet, the opening degree is closer to the predetermined upper limit opening degree. The exhaust damper opening determining means for determining the opening degree of the outlet damper of each outlet in consideration of the required air volume of each outlet so as to approach, and the opening determined by the outlet damper opening determining means Control the blowout damper of each outlet It is characterized in further comprising a blowout damper control unit that.

  Further, in one configuration example of the air volume control system of the present invention, the blow damper opening determining means selects the first blow damper provided at the blow outlet having the maximum required air volume among the blow outlets, The second blow damper is provided for the first blow damper opening determining means that uses the opening of the first blow damper as the upper limit and the second blow damper other than the first blow damper. The ratio of the required air volume of the outlet and the required air volume of the outlet provided with the first outlet damper is calculated, and from the product of this ratio and the upper limit opening degree, the second outlet damper It is characterized by comprising second blow damper opening degree determining means for calculating the opening degree.

In addition, one configuration example of the air volume control system of the present invention includes a required air volume total value calculating unit that calculates a total value of required air volumes of each outlet when the air volume setting request is a required air volume value, and the air conditioner. Supply air volume control means for controlling the fan rotation speed of the air conditioner so that the air volume of the supply air supplied from the air-conditioner matches the total value of the required air volumes.
Further, in one configuration example of the air volume control system of the present invention, when the air volume setting request is the required air volume ratio, the required air volume of the variable air volume unit is set using the measured value and the set value of the temperature sensor in each room. A plurality of blowing damper units send a required amount of air flow to each controlled area.

  Further, the air volume control method of the present invention includes a required air volume determining step for determining a required air volume of each air supply outlet according to an air volume setting request from a resident, and a blowout of each air outlet from the required air volume of each air outlet. Compared to the case where the damper opening is determined independently, the required air volume of each outlet is comprehensively taken into consideration so that the opening approaches the predetermined upper limit opening. A blow damper opening determining step for determining the opening, and a blow damper control step for controlling the blow damper at each outlet so as to be the opening determined in the blow damper opening determining step. Is.

  According to the present invention, the opening degree is closer to the predetermined upper limit opening degree than in the case where the opening degree of the blowing damper of each outlet is determined independently from the required air volume of each outlet as in the prior art. As described above, the opening degree of the blowing damper of each outlet is determined in consideration of the required air volume of each outlet, so that the intermediate opening degree of the blowing damper is changed to a state where the opening degree is as large as possible. Since it can be transferred, any combination of air volume setting requirements can reduce the pressure loss of the entire duct system, minimize fan power loss, and realize energy saving. .

It is a block diagram which shows the structure of the air volume control system which concerns on embodiment of this invention. It is a block diagram which shows the structure of the blowing damper control part of the air volume control system which concerns on embodiment of this invention. It is a block diagram which shows the structure of the air-conditioning control apparatus of the air volume control system which concerns on embodiment of this invention. It is a flowchart explaining the operation | movement when there exists an air volume setting request | requirement from the resident in the air volume control system which concerns on embodiment of this invention. It is a figure explaining the effect in case the request | requirement air volume ratio of each blower outlet is the same in the air volume control system which concerns on embodiment of this invention. It is a figure explaining the effect in case the required air volume ratio of each blower outlet differs in the air volume control system concerning an embodiment of the invention. It is a figure explaining the increase in fan power loss by pressure loss.

[Principle of the Invention]
In an air conditioning system in which a blow damper is provided between a conventional VAV and a blow outlet, each blow damper is controlled independently, so that fan power loss due to pressure loss occurs at an intermediate opening. On the other hand, in the present invention, since the state of the intermediate opening degree of the blowout damper is shifted to a state where the opening degree is as large as possible based on the request information of the blowout port, the pressure loss of the entire duct system is reduced. . Therefore, fan power loss can be reduced.

[Embodiment]
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the configuration of an air volume control system (VAV and blowing damper air conditioning system) according to an embodiment of the present invention.
The air volume control system of the present embodiment includes an air conditioner 1, an air supply duct 4 that supplies air supply from the air conditioner 1 to the controlled areas 8-1-1 to 8-2-3, and the controlled area 8. -1-1 to 8-2-3 VAV units 5-1 to 5-2, which are variable air volume units for controlling the amount of supply air for each supply air outlet, and VAV units 5-1 to 5-5 VAV control units 10-1 to 10-2 that are control devices that control 2 and the amount of air supplied to controlled areas 8-1-1 to 8-2-3 for each supply air outlet or a plurality of air outlets Air volume setting from the residents of the blowout damper units 6-1-1 to 6-2-3 and the controlled areas 8-1-1 to 8-2-3 controlled for each set of exits (that is, for each blowout damper) The air volume setting devices 11-1-1 to 11-2-3 that receive the request and the air conditioning control device 12 that controls the air conditioner 1 are configured. The air volume setting request may be given as a required air volume value or may be given as a required air volume ratio, but in the following, a case where it is given as a required air volume value will be described as an example for ease of explanation.

  The air conditioner 1 has a heat exchanger 2 and a fan 3 having a variable air volume, and sends the supply air cooled or heated by the heat exchanger 2 to the controlled areas 8-1-1 to 8-2-3. The VAV units 5-1 to 5-2, the VAV control units 10-1 to 10-2, and the blowing damper control units 123-1 to 123-2 are provided for each VAV system for supplying air. The blowout damper units 6-1-1 to 6-2-3 are provided for the air supply outlets 9-1-1 to 9-2-3. Blowing damper units 7-1-1 to 7-2-3 are respectively provided in the blowing damper units 6-1-1 to 6-2-3, and the blowing damper units 6-1-1 to 6-2 are provided. -3 can be controlled in the amount of air supply that passes.

  The air cooled or heated by the heat exchanger 2 is sent out by the fan 3. The air (air supply) sent out by the fan 3 is blown out through the air supply duct 4 to the blowout damper units 6-1-1 to 6-2-3 in the controlled areas 8-1-1-1 to 8-2-3. Is supplied to the controlled areas 8-1-1 to 8-2-3 through the blowing damper units 6-1-1 to 6-2-3.

The air conditioning control device 12 calculates the total value of the required air volume of the entire system, calculates the fan rotation speed corresponding to the total value of the required air volume, and controls the air conditioner 1 so that the calculated fan rotation speed is obtained. In addition, the air conditioning control device 12 includes the heat exchanger 2 so that the supply air temperature measurement value measured by a temperature sensor (not shown) installed for each of the VAV units 5-1 to 5-2 matches the supply air temperature setting value. The amount of heat medium (cold water or hot water) supplied to the is controlled.
The above operation is the same as that of the conventional air volume control system.

  Next, features of the present embodiment will be described. FIG. 2 is a block diagram showing the configuration of the blowout damper control unit 123-1. The blowing damper control unit 123-1 includes a required air volume determining unit 1230, an air volume setting-requested air volume storage unit 1231, a first blowing damper opening degree determining unit 1232, a second blowing damper opening degree determining unit 1233, It has a blowing damper opening notifying unit 1234, a blowing damper control unit 1235, and a required air volume notifying unit 1236.

  The required air volume determination unit 1230 determines the required air volume of each of the outlets 9-1-1 to 9-1-3. The first blow damper opening determining unit 1232 selects a blow damper provided at the blow outlet having the maximum required air volume among the blow outlets 9-1-1 to 9-1-3, and opens the blow damper. Determine the degree. The second blowing damper opening determining unit 1233 determines the opening of the remaining blowing damper. The blow damper opening degree notification unit 1234 notifies the damper control unit 1235 of the blow damper opening degree determined by the first blow damper opening degree determination unit 1232 and the second blow damper opening degree determination unit 1233. The blowout damper control unit 1235 controls the blowout dampers 7-1-1 to 7-1-3 of the blowout ports 9-1-1 to 9-1-3. The required air volume notifying unit 1236 notifies the air conditioning control device 12 of the value of the required air volume of each of the outlets 9-1-1 to 9-1-3 determined by the required air volume determining unit 1230.

  The structure of the blowing damper control unit 123-2 is the same as that of the blowing damper control unit 123-1.

FIG. 3 is a block diagram showing a configuration of the air conditioning control device 12. The air conditioning control device 12 includes an air supply temperature control unit 120, an air supply air volume control unit 121, a required air volume total value calculation unit 122, and blowout damper control units 123-1 to 123-2.
The supply air temperature control unit 120 controls the amount of the heat medium supplied to the heat exchanger 2 (specifically, controls the opening degree of the cold water valve or the hot water valve), thereby supplying the air supply supplied by the air conditioner 1. Control the temperature of qi. The supply air volume control unit 121 controls the air volume of the supply air supplied by the air conditioner 1 by controlling the fan rotation speed of the air conditioner 1. The required air volume total value calculation unit 122 calculates the total required air volume. The blowout damper control units 123-1 to 123-2 control the amount of air blown from each of the blowout outlets 9-1-1 to 9-2-3 by controlling the opening degree of the blowout damper for each VAV system.

Next, the operation of the air volume control system when an air volume setting request is received from a resident will be described with reference to FIG.
Residents in each controlled area 8-1-1-8-2-3 operate the air volume setting devices 11-1-1 to 11-2-3 to set the air volume so that it becomes a thermal environment desired by themselves. To change. The air volume setting request according to this operation is transmitted from the air volume setting units 11-1-1 to 11-2-3 to the blow damper control units 123-1 to 123-2.

  When the required air volume determination unit 1230 of the blowout damper control unit 123-1 receives the air volume setting request from the air volume setting units 11-1-1-1 to 11-2-3 (YES in step S1 in FIG. 4), this air volume setting request. Accordingly, the required air volume Q of each of the air outlets 9-1-1 to 9-2-3 is determined (step S2). In the air volume setting / required air volume storage unit 1231, the class value of the air volume setting and the actual required air volume value are registered in advance in the form of a table. In the present embodiment, the class value of the air volume setting is assumed to be three values of H (large), M (medium), and L (small). The required air volume determining unit 1230 determines the required air volume Q by acquiring the value of the required air volume Q corresponding to the class value indicated by the air volume setting request from the air volume setting-requested air volume storage unit 1231 (step S2). The required air volume determining unit 1230 performs the process for determining the required air volume Q for each outlet or each set of a plurality of outlets (that is, for each outlet damper). The current required air volume Q is maintained for the air outlets that have not issued an air volume setting request that instructs to change the air volume setting.

Next, about the system | strain connected to each to-be-controlled area side of VAV5-1, the 1st blowing damper opening degree determination part 1232 of the blowing damper control part 123-1 is each blowing outlet 9-1-1-9-. A blower damper 7-1-i (i is 1 to 3) provided at the blowout port 9-1-i having the maximum required airflow rate Q is selected from 1 to 3 (step S 3), and the blower damper 7-1 is selected. determining the opening degree D _i of -i (step S4). The required air volume Q of the air outlet 9-1-i is set as the maximum required air volume Q _max . The first blow-out damper opening degree determination unit 1232 to the upper limit opening degree D _max to the opening D _i of the blowout dampers 7-1-i was selected is predefined in step S3 (e.g., 100%) (Step S4) .

On the other hand, the second blower damper opening degree determining unit 1233 of the blower damper control unit 123-1 is a blower damper 7-1- other than the blower damper 7-1-i selected by the first blower damper opening degree determining unit 1232. For j (j is 1 to 3 and i ≠ j), the ratio between the required air volume Q _j of the air outlet 9-1-j provided with the outlet damper 7-1- _j and the maximum required air volume Q _max calculating a ratio R _j is as follows (step S5).
R _j = Q _j / Q _max (1)

The 2nd blowing damper opening degree determination part 1233 performs calculation of Formula (1) for every blowing damper other than the blowing damper 7-1-i. Then, the second blow-out damper opening degree determining section 1233, the product of the magnification R _j of the predefined upper opening D _max and outlet damper 7-1-j calculated in step S5, the blowout dampers 7-1 The opening degree D _j of −j is calculated (step S6).
D _j = R _j D _max (2)

The 2nd blowing damper opening degree determination part 1233 performs calculation of Formula (2) for every blowing damper other than the blowing damper 7-1-i. The blow damper control unit 1235 of the blow damper control unit 123-1 uses the blow damper opening degrees D _i and D _j determined by the first blow damper opening degree determination unit 1232 and the second blow damper opening degree determination unit 1233. Then, the blow damper is controlled so as to have the respective opening degrees of the blow dampers 7-1-1 to 7-1-3 (step S7).

  The operation of the blowing damper control unit 123-2 is the same as that of the blowing damper control unit 123-1.

On the other hand, the operation on the air conditioning control device 12 side will be described. The required air volume Q of each of the outlets 9-1-1 to 9-1-3 determined by the required air volume determining unit 1230 in step S2 is the required air volume notifying unit. 1236 notifies the required air volume total value calculation unit 122 of the air conditioning control device 12, and the required air volume total value calculation unit 122 determines the total required air volume of the entire system, that is, the outlets 9-1-1 to 9-2-3. The total value Q _AHU of the required air volume Q is calculated (step S8).

The supply air volume control unit 121 of the air conditioning control device 12 calculates an inverter output value corresponding to the total value Q _AHU of the required air volume Q calculated by the required air volume total value calculation unit 122 (step S9), and this inverter output value is calculated. By giving to the motor of the fan 3 of the air conditioner 1, the fan rotation speed of the air conditioner 1 is controlled (step S10). In this way, the air volume of the supply air is controlled so that the total value Q _AHU of the required air volumes Q can be secured.

With the above configuration, in the present embodiment, the fan rotation speed is approximately a numerical value obtained by dividing the fan rotation speed obtained by the conventional technique by the average value of the magnification R _j . Therefore, it is possible to control the air volume with the blow-out damper opening pattern and the fan rotation speed with reduced pressure loss as compared with the prior art.

Hereinafter, two examples will be given as specific examples. Here, as shown in Table 1, when the class value of the air volume setting at the outlet is H, the required air volume is 100 m ³ / h, and when the class value of the air volume setting is M, the required air volume is 70 m ³ / h. When the set class value is L, the required air volume is 40 m ³ / h. That is, the contents corresponding to Table 1 are stored in the air volume setting / required air volume storage unit 91.

  In the case of the prior art, when the required air volume is determined, the blowout damper opening is also determined. When the class value is H, the blowing damper opening is 100%, when the class value is M, the blowing damper opening is 70%, and when the class value is L, the blowing damper opening is 40%.

[Specific Example 1]
In the specific example 1, the case where the class value of the air volume setting of all the outlets 9-1-1 to 9-1-3 is set to M is taken as an example. In the prior art, as shown in FIG. 5A, the opening degree of each of the blowing dampers 7-1-1 to 7-1-3 is 70%, and the air volume supplied by the air conditioner 1 is 70 × 3 = 210 m ^3. / H.

  On the other hand, in this embodiment, since all the required air volumes of the air outlets 9-1-1 to 9-1-3 are the maximum air outlets, as shown in FIG. All of the blow dampers 7-1-1 to 7-1-3 from 1 to 9-1-3 have the upper limit opening (for example, 100%). Therefore, since the opening amount of the blow damper is larger than that in the case of the prior art, energy loss can be realized by reducing the pressure loss and the fan rotational speed.

[Specific Example 2]
Specific example 2 is an example in which the airflow setting class value of the air outlets 9-1-1 and 9-1-2 is L, and the airflow setting class value of the air outlet 9-1-3 is M. In the prior art, as shown in FIG. 6 (A), the opening degree of the blowing dampers 7-1-1 and 7-1-2 is 40% and the opening degree of the blowing damper 7-1-3 is 70%. The air volume supplied by the machine 1 is 40 + 40 + 70 = 150 m ³ / h.

On the other hand, in this Embodiment, since the request | requirement air volume of the blower outlet 9-1-3 becomes the largest blower outlet, as shown to FIG. 6 (B), the blower damper 7-1- of the blower outlet 9-1-3. 3 is the upper limit opening (for example, 100%). From the required air volume of the outlets 9-1-1～9-1-3 magnification R ₁ of the outlet damper 7-1-1 is required air volume of the air damper 7-1-1 and outlet damper 7-1-3 The required air volume is 0.57 (= 40 m ³ / h / 70 m ³ / h). Likewise, it obtained magnification R ₂ also 0.57 blowout dampers 7-1-2. Since the opening degree of the blowout damper 7-1-3 at the blowout outlet 9-1-3 where the required air volume is maximum is 100%, the opening degree of the blowout dampers 7-1-1 and 7-1-2 is 57%. (= 100% × 0.57). In the present embodiment, the total required air volume is 150 m ³ / h as in the case of the prior art, but since the blower damper opening generally increases as compared with the case of the prior art, the pressure loss As a result, the number of fan rotations can be reduced.

Here, the air volume settings set by the air volume setting units 11-1-1 to 11-2-3 are converted into the required air volume values of the blowing dampers 7-1-1 to 7-2-3 according to the list of Table 1. Instead of the required air volume value, it may be converted into the required air volume ratio. In this case, a required air volume ratio determining unit may be provided in each of the blowing damper control units 123-1 to 123-2 instead of the required air volume determining unit 1230. The first blow damper opening degree determination unit 1232 and the second blow damper opening degree determination unit 1233 use the required air volume ratio instead of the required air volume Q, and use the maximum required air volume ratio instead of the maximum required air volume Q _max. Thus, the opening degree of each of the blowing dampers 7-1-1 to 7-2-3 may be determined. Control of the air volume to each controlled area 8-1-1 to 8-2-3 is performed by a temperature sensor installed in each VAV 5-1 to 5-2. In the blowout damper units 6-1-1 to 6-2-3, the air flow amount controlled by the VAVs 5-1 to 5-2 is in the opening state for each ratio to be distributed. Control is performed so that the ratio of the blowout damper 7-1-i (i is 1 to 3) becomes the upper limit opening degree. The above VAV operation is the same as that of the conventional air volume control system.

  Note that each of the blowout damper control units 123-1 to 123-2 and the air conditioning control device 12 of the present embodiment controls a computer having a CPU, a storage device, and an external interface, and these hardware resources. It can be realized by a program. The CPU of each device executes the processing described in this embodiment in accordance with a program stored in the storage device.

  The present invention can be applied to an air volume control system including an air conditioner, a variable air volume unit, and a plurality of blowing damper units.

  DESCRIPTION OF SYMBOLS 1 ... Air conditioner, 2 ... Heat exchanger, 3 ... Fan, 4 ... Air supply duct, 5-1 to 5-2 ... VAV unit, 6-1-1 to 6-2-3 ... Outlet damper unit, 7-1 -1 to 7-2-3 ... blowing damper, 8-1-1 to 8-2-3 ... controlled area, 9-1-1 to 9-2-3 ... blowing outlet, 10-1 to 10-2 ... VAV control unit, 11-1-1 to 11-2-3 ... Air volume setting device, 12 ... Air conditioning control device, 1230 ... Required air volume determining unit, 1231 ... Air volume setting-Required air volume storage unit, 1232 ... First blowing Damper opening determination unit, 1233 ... second blowing damper opening determination unit, 1234 ... blowing damper opening notification unit, 1235 ... blowing damper control unit, 1236 ... required air volume notification unit, 120 ... supply air temperature control unit, 121 ... Supply air volume control unit, 122 ... Required air volume total value calculation unit, 123-1 to 123-2 ... Blowout damper Control unit.

Claims (8)

An air conditioner equipped with a fan for sending out air supply;
A variable air volume unit provided in an air supply system supplied from the air conditioner;
A plurality of blowing damper units each provided with a blowing damper that is provided for each of the supply air outlets or sets of a plurality of outlets that are sent through the variable air volume unit, and that controls the air volume of the supply air;
A required air volume determining means for determining a required air volume of each air supply outlet according to an air volume setting request from a resident;
Covers the required air volume at each outlet so that the opening approaches the predetermined upper limit opening rather than determining the opening of the blow damper at each outlet independently from the required air volume at each outlet. Blowing damper opening determining means for determining the opening of the blowing damper of each outlet,
An air volume control system comprising: a blow damper control means for controlling the blow damper of each blow outlet so that the blow damper opening determining means has a determined opening. The air volume control system according to claim 1,
The blowing damper opening determining means is
A first blowing damper opening degree determination is made by selecting a first blowing damper provided at the blowing outlet having the maximum required air volume among the respective blowing outlets, and setting the opening degree of the first blowing damper as the upper limit opening degree. Means,
About the 2nd blower dampers other than the 1st blowout damper, the demand air volume of the blower outlet in which this 2nd blower damper is provided, and the demanded air volume of the blower outlet in which the 1st blower damper is provided An air volume control system comprising: a second blowing damper opening determining means for calculating a ratio and calculating the opening of the second blowing damper from the product of the ratio and the upper limit opening. The air volume control system according to claim 1 or 2,
When the air volume setting request is a required air volume value,
A required air volume total value calculating means for calculating a total value of required air volumes of each outlet;
An air volume control system comprising air supply air volume control means for controlling the fan rotation speed of the air conditioner so that the air volume of the air supplied from the air conditioner matches the total value of the required air volumes. The air volume control system according to claim 1 or 2,
When the air volume setting request is a required air volume ratio,
The air volume characterized by setting the required air volume of the variable air volume unit using the measured value and set value of the temperature sensor in each room, and sending the required air volume to each controlled area by a plurality of blowing damper units Control system. A required air volume determination step for determining a required air volume of each air supply outlet according to an air volume setting request from a resident;
Covers the required air volume at each outlet so that the opening approaches the predetermined upper limit opening rather than determining the opening of the blow damper at each outlet independently from the required air volume at each outlet. Blowing damper opening determining step for determining the opening of the blowing damper of each outlet,
An air volume control method comprising: a blow damper control step for controlling the blow damper of each blow outlet so as to have the opening determined in the blow damper opening determining step. In the air volume control method according to claim 5,
The blowing damper opening determining step includes:
A first blowing damper opening degree determination is made by selecting a first blowing damper provided at the blowing outlet having the maximum required air volume among the respective blowing outlets, and setting the opening degree of the first blowing damper as the upper limit opening degree. Steps,
About the 2nd blower dampers other than the 1st blowout damper, the demand air volume of the blower outlet in which this 2nd blower damper is provided, and the demanded air volume of the blower outlet in which the 1st blower damper is provided An air volume control method comprising: a second blowing damper opening determining step for calculating a ratio and calculating an opening of the second blowing damper from a product of the ratio and the upper limit opening. In the air volume control method according to claim 5 or 6,
When the air volume setting request is a required air volume value,
A required air volume total value calculating step for calculating a total value of required air volumes of each outlet;
An air volume control method comprising: an air supply air volume control step for controlling a fan rotation speed of the air conditioner so that an air volume of the air supplied from the air conditioner coincides with a total value of the required air volumes. In the air volume control method according to claim 5 or 6,
When the air volume setting request is a required air volume ratio,
An air volume control method comprising: setting a required air volume of a variable air volume unit using a measured value and a set value of a temperature sensor in each room, and sending each requested air volume to each controlled area by a plurality of blowing dampers.

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