JP2021001711A - Air conditioning system - Google Patents

Abstract

To reduce cost to attain a conditioning function when air quantity is low in an air conditioning system.SOLUTION: An air conditioning system 10 includes: an air handling unit 20 having a heat exchanger 22 and a first fan 21; a plurality of fan units 30 each having a second fan 31 blowing out supply air to an object space 100; a duct 40 distributing the supply air blown out from the air handling unit 20 to the first fan 21 to the plurality of fan units 30; and a controller 50 controlling the first fan 21. The controller 50 stops an operation of the first fan 21, when conditions where rotational frequency of at least one of the plurality of second fans 31 is equal to or smaller than predetermined rotational frequency, supply air quantity of the fan unit 30 having the second fan 31 whose rotational frequency is equal to or smaller than the predetermined rotational frequency is a value of target air quantity or greater and amount of air blown out from the air handling unit 20 reaches a threshold value or smaller are satisfied.SELECTED DRAWING: Figure 1

Description

Air conditioning system with air handling unit

Conventionally, for example, as described in Patent Document 1 (Japanese Unexamined Patent Publication No. 10-253132), an air conditioning unit having a heat exchanger and an air conditioning fan, a plurality of ventilation units having a blower fan, and an air conditioning unit Air conditioning systems are known that include a duct that distributes conditioned air to the ventilation unit. In this air conditioning system, the rotation speed of the blower fan is controlled for air conditioning in the room.

However, in the air conditioning system described in Patent Document 1, when the blower fan of the ventilation unit is driven at the minimum rotation speed, an electric shutter or an electric damper or the like is used to further adjust the amount of air blown from the ventilation unit. Configuration is required.

Such an air conditioning system has a problem of reducing the cost for realizing the adjustment function when the air volume is small.

The air conditioning system of the first aspect is composed of an air handling unit having a heat exchanger through which a heat medium flows and a first fan, a plurality of fan units each having a second fan for blowing supply air into a target space, and an air handling unit. A duct for distributing the supply air sent by the first fan to a plurality of fan units and a controller for controlling the first fan are provided, and at least one of the plurality of second fans has a predetermined rotation speed. Below, when the condition that the air volume of the fan unit having the second fan having the predetermined rotation speed or less is equal to or more than the target value and the amount of air sent from the air handling unit is equal to or less than the threshold value is satisfied, the first 1 Stop the operation of the fan.

In the air conditioning system of the first aspect, the controller stops the operation of the first fan, so that the air volume of the fan unit having the second fan having a predetermined rotation speed or less can be easily made equal to or less than the target value. By realizing the adjustment when the air volume is small by controlling the controller, it is possible to reduce the cost for realizing the adjustment function when the air volume is small.

The air conditioning system of the second viewpoint is the system of the first viewpoint, and the predetermined rotation speed is the minimum rotation speed of the second fan.

In the air conditioning system of the second aspect, the controller stops the operation of the first fan, so that the air volume of the fan unit having the second fan having the minimum rotation speed can be easily made equal to or less than the target value.

The air conditioning system of the third viewpoint is a system of the first viewpoint or the second viewpoint, and the controller sets the environment of the target space to the setting environment set to at least one fan unit among the plurality of fan units. When the state in which the air volume of at least one fan unit has not reached the target value continues for a predetermined time, the operation of the first fan which satisfies the condition and is stopped is restarted.

In the air conditioning system of the third aspect, the controller restarts the operation of the first fan to shorten the time for the air volume of the fan unit to reach the target value and to quickly reach the set environment in the target space.

The conceptual diagram which shows the structure of the air-conditioning system which concerns on embodiment. A block diagram for explaining the configuration of the controller. A flowchart for explaining the characteristic operation of the air conditioning system. The conceptual diagram which shows the other example of the structure of the air conditioning system which concerns on the modification.

(1) Overall Configuration The air conditioning system 10 shown in FIG. 1 includes an air handling unit 20, a fan unit 30, a duct 40, and a controller 50. The air handling unit 20 has a first fan 21 and a heat exchanger 22. Each of the plurality of fan units 30 has a second fan 31. Each second fan 31 supplies air from the fan unit 30 to the target space 100. The target space 100 is, for example, a room in a building. A room is, for example, a space in which the movement of air is restricted by floors, ceilings and walls. A plurality of fan units 30 are arranged with respect to one or a plurality of target spaces 100. FIG. 1 shows an example in which an air conditioning system 10 including two fan units 30 is arranged with respect to one target space 100 as a typical example of an air conditioning system 10 including a plurality of fan units 30. ing. The number of fan units 30 may be 3 or more, and is appropriately set. As described above, the target space 100 in which the fan unit 30 is arranged may be two or more.

The duct 40 distributes the air SA sent from the air handling unit 20 by the first fan 11 to the plurality of fan units 30. Here, all the air blown out from the first fan 21 is configured to flow into the duct 40.

Each fan unit 30 and the target space 100 are connected by a ventilation passage 81. Each second fan 31 generates an air flow from the duct 40 toward the ventilation passage 81 in the fan unit 30. Each second fan 31 can change the static pressure in each fan unit 30 (in front of the ventilation passage 81) by changing the rotation speed. Assuming that the static pressure of the duct 40 is constant, each of the second fans 31 can increase the static pressure in each fan unit 30 (in front of the ventilation passage 81) by increasing the rotation speed. When the static pressure in the fan unit 30 becomes high, the amount of air in the air SA flowing through the ventilation passage 81 increases. By changing the amount of air flowing in this way, the amount of air supply air blown from the outlet 81b of each ventilation path 81 to the target space 100 changes.

The controller 50 includes a main controller 51 and a plurality of sub-controllers 52. The main controller 51 and the plurality of sub-controllers 52 are connected to each other to form the controller 50. The main controller 51 controls the output of the first fan 21. When the output of the first fan 21 increases, the state of the first fan 21 changes in the direction in which the amount of air blown by the first fan 21 increases.

One sub-controller 52 is provided for each fan unit 30. Each sub-controller 52 issues an instruction regarding the air volume change to the corresponding second fan 31. Each sub-controller 52 stores the target air volume. Each sub-controller 52 issues an instruction (instruction regarding changing the air volume) to increase the rotation speed of the second fan 31 if the supply air volume is insufficient with respect to the target air volume. On the contrary, if the supply air volume is excessive with respect to the target air volume, the sub controller 52 issues an instruction (instruction regarding changing the air volume) to reduce the rotation speed of the second fan 31.

The controller 50 obtains information on the amount of air supplied to the target space 100 by the plurality of second fans 31. The information on the amount of air is, for example, the amount of air to be supplied to the target space 100 per second, and in other words, the amount of air to be supplied is the required amount of air supply. The required output of the first fan 21 is determined based on the obtained air amount information. The controller 50 controls the output of the first fan 21 so as to obtain the determined required output. Specifically, each sub-controller 52 obtains information on the amount of air in the fan unit 30 from the corresponding fan unit 30. Each sub-controller 52 outputs information on the amount of air to the main controller 51.

In controlling the output of the first fan 21, in particular, the controller 50 has an air volume of a fan unit 30 having a second fan 31 in which at least one of the plurality of second fans 31 has a predetermined rotation speed or less. When the condition that is equal to or higher than the target value (target air volume value) and the amount of air sent from the air handling unit 20 is equal to or lower than the threshold value is satisfied, the operation of the first fan 21 is stopped. When the operation of the first fan 21 is stopped in such a state, the static pressure of the duct 40 connected to the fan unit 30 decreases, and even the second fan 31 having a predetermined rotation speed or less is sent out to the ventilation passage 81. It becomes easy to reduce the air supply air volume.

(2) Detailed configuration (2-1) Air handling unit 20
The air handling unit 20 includes a first air volume detecting means 23, a temperature sensor 24, and a water volume adjusting valve 25, in addition to the first fan 21 and the heat exchanger 22 described above. For example, cold water or hot water is supplied to the heat exchanger 22 as a heat medium from the heat source unit 60. The heat medium supplied to the heat exchanger 22 may be something other than cold water or hot water, for example brine. For the first air volume detecting means 23, for example, an air volume sensor, a wind speed sensor, or a differential pressure sensor can be used. The first air volume detecting means 23 detects the air volume blown by the first fan 21. The first air volume detecting means 23 is connected to the main controller 51. The value of the air volume detected by the first air volume detecting means 23 is transmitted from the first air volume detecting means 23 to the main controller 51. The air volume detected by the first air volume detecting means 23 is the air volume flowing through the duct 40. In other words, the air volume detected by the first air volume detecting means 23 is the total amount of the supplied air volume supplied from the plurality of fan units 30 to the target space 100.

The temperature sensor 24 detects the temperature of the air SA sent from the first fan 21 to the duct 40. The temperature sensor 24 is connected to the main controller 51. The temperature value detected by the temperature sensor 24 is transmitted from the temperature sensor 24 to the main controller 51.

The air handling unit 20 is connected to the target space 100 via the ventilation passage 82. The air RA returned from the target space 100 through the ventilation passage 82 is sent out to the duct 40 through the heat exchanger 22 by the first fan 21. When passing through the heat exchanger 22, the air RA exchanges heat with the cold or hot water flowing through the heat exchanger 22 to become conditioned air. The amount of heat given to the air SA that exchanges heat with the heat exchanger 22 and is sent to the duct 40 is adjusted by the water amount adjusting valve 25. The opening degree of the water amount adjusting valve 25 is controlled by the main controller 51. As the opening degree of the water amount adjusting valve 25 increases, the amount of water flowing through the heat exchanger 22 increases, and the amount of heat exchanged between the heat exchanger 22 and the air SA per unit time increases. On the contrary, when the opening degree of the water amount adjusting valve 25 becomes small, the amount of water flowing through the heat exchanger 22 decreases, and the amount of heat exchanged between the heat exchanger 22 and the air SA per unit time decreases.

(2-2) Fan unit 30
The fan unit 30 has a second air volume detecting means 32 in addition to the second fan 31 already described. The second air volume detecting means 32 detects the air volume blown by the second fan 31. Each second air volume detecting means 32 is connected to one corresponding sub-controller 52. The value of the air volume detected by the second air volume detecting means 32 is transmitted to the sub controller 52. The air volume detected by the second air volume detecting means 32 is the air volume flowing through the ventilation passage 81. In other words, the air volume detected by the second air volume detecting means 32 is the air supply air volume supplied from each fan unit 30 to the target space 100. For the second air volume detecting means 32, for example, an air volume sensor, a wind speed sensor, or a differential pressure sensor can be used.

(2-3) Controller 50
The controller 50 is realized by a computer. The controller 50 includes control arithmetic units 51a and 52a and storage devices 51b and 52b. A processor such as a CPU or GPU can be used for the control arithmetic units 51a and 52a. The control arithmetic units 51a and 52a read the programs stored in the storage devices 51b and 52b, and perform predetermined image processing and arithmetic processing according to the programs. Further, the control arithmetic units 51a and 52a can write the arithmetic results in the storage devices 51b and 52b and read the information stored in the storage devices 51b and 52b according to the program. FIG. 2 shows various functional blocks realized by the control arithmetic units 51a and 52a. The storage devices 51b and 52b can be used as a database.
(2-4) Remote sensor 70
The plurality of remote sensors 70 have a function of a temperature sensor. Each remote sensor 70 is configured to transmit data indicating the temperature of the target space 100 to the corresponding sub-controller 52.

(3) Operation of the air conditioning system 10 (3-1) Outline of operation Each of the plurality of sub-controllers 52 receives the detected temperature value of the target space from the connected remote sensor 70. Each sub-controller 52 holds data indicating the set temperature. For example, data indicating the set temperature is transmitted in advance to each sub-controller 52 from a remote controller (not shown) or the like. Each sub-controller 52 stores data indicating a set temperature received from a remote controller or the like in a storage device 52b (see FIG. 2) such as a built-in memory. Each sub-controller 52 transmits a set temperature value to the main controller 51. The main controller 51 determines the target air volume of each fan unit 30 according to the temperature detected by the corresponding remote sensor 70 based on the set temperature. The main controller 51 transmits the value of the target air volume to each sub controller 52. In each fan unit 30, the rotation speed of the second fan 31 is adjusted by the corresponding sub-controller 52.

Each sub-controller 52 controls the rotation speed of each second fan 31 in order to match the supply air volume with the target air volume. The plurality of sub-controllers 52 control the rotation speeds of the plurality of second fans 31 independently of each other. If the air volume detected by the second air volume detecting means 32 is smaller than the target air volume, each sub-controller 52 increases the rotation speed of each second fan 31. If the air volume detected by the second air volume detecting means 32 is larger than the target air volume, each sub-controller 52 reduces the rotation speed of each second fan 31.

(3-2) Characteristic Operation Next, the characteristic operation in the air conditioning system 10 will be described along with the flow shown in FIG. A characteristic operation in the air conditioning system 10 is an operation performed when the rotation speed of the second fan 31 becomes a predetermined rotation speed or less.

Each sub-controller 52 stores the value of the air volume detected by the second air volume detecting means 32 of each corresponding fan unit 30 in the storage device 52b (step ST1). When the rotation speed of the second fan 31 becomes equal to or less than the predetermined rotation speed stored in the storage device 52b in advance while the fan unit 30 is supplying air to the target space 100, the sub-controller 52 moves the second fan 31. It is determined that the rotation speed of the fan 31 is equal to or less than the predetermined rotation speed.

The sub-controller 52 that determines that the rotation speed of the second fan 31 is equal to or less than the predetermined rotation speed determines whether or not the supply air volume of the fan unit 30 having the second fan 31 is equal to or greater than the target air volume. The sub-controller 52 that determines that the supply air volume is equal to or higher than the target air volume transmits information to the main controller 51 that the rotation speed of the second fan 31 is equal to or lower than the predetermined rotation speed and the supply air volume is equal to or higher than the target air volume. This predetermined rotation speed is, for example, a minimum rotation speed of the second fan 31 or a value slightly higher than the minimum rotation speed. Values slightly higher than the minimum rotation speed are, for example, minimum rotation speed × 1.05, minimum rotation speed × 1.1, and minimum rotation speed × 1.2.

Upon receiving the information that the rotation speed of the second fan 31 is equal to or less than the predetermined rotation speed and the supply air volume is equal to or higher than the target air volume, the main controller 51 uses the detection value of the first air volume detecting means 23 to use the detection value of the first air volume detecting means 23 to use the detection value of the air handling unit 20 It is determined whether or not the amount of air sent from the air conditioner is equal to or less than the threshold value (step ST2). This threshold value is written in advance in the storage device 51b of the main controller 51. When the main controller 51 determines that the first condition is satisfied (Yes in step ST2), the main controller 51 stops the operation of the first fan 21 (step ST3). After that, with the first fan 21 stopped, air conditioning of the target space 100 is performed only by the plurality of second fans 31 (step ST4). Here, the first condition is that at least one of the plurality of second fans 31 has a predetermined rotation speed or less, and the air supply air volume of the fan unit 30 having the second fan 31 having a predetermined rotation speed or less is equal to or more than the target air volume value. Moreover, it is a condition that the amount of air sent from the air handling unit 20 is equal to or less than the threshold value. Even if the first fan 21 is stopped, a sufficient amount of air supply air is secured for the target space 100 by the plurality of second fans 31. In this way, a sufficient amount of air supply air is secured for the target space 100 even if the amount of air sent from the air handling unit 20 is equal to or less than the threshold value and the first fan 21 is stopped. This is because it has been confirmed in step ST2 that a sufficient amount of air supply air is secured only by the second fan 31 of the above.

The main controller 51 receives the set temperature set for the temperature of the target space 100 from the plurality of sub-controllers 52. The main controller 51 receives the temperature values detected by the plurality of remote sensors 70 via the sub controller 52. The main controller 51 compares the set temperature with the temperature value, and whether the temperature value of the target space 100 has reached the set temperature set for at least one fan unit 30 among the plurality of fan units 30. Judge whether or not.

Further, the main controller 51 monitors through the sub controller 52 whether or not the supply air volume of the fan unit 30 that has not reached the set temperature has not reached the target air volume for a predetermined time. This predetermined time is written in advance in the storage device 51b of the main controller 51. When the next second condition is satisfied (Yes in step ST5), the main controller 51 restarts the operation of the first fan 21 that has been stopped due to the satisfaction of the first condition (Yes). Step ST6). In other words, if the cause of the stoppage of the first fan 21 is other than satisfying the first condition, the operation of the first fan 21 is not restarted. For example, when the operation of the first fan 21 is stopped by the detection of the failure of the first fan 21, the operation of the first fan 21 is not restarted even if the second condition is satisfied. In this second condition, the set temperature set for at least one fan unit 30 among the plurality of fan units 30 has not been reached, and the air supply air volume of at least one fan unit 30 has reached the target air volume value. It is a condition that the state of not being used continues for a predetermined time. If there is no instruction to stop the system (No in step ST7), the process returns to the first step ST1 and the operations of steps ST1 to ST7 are repeated. If there is an instruction to stop the system, these series of operations are terminated.

(4) Modification example (4-1) Modification example 1A
As shown in FIG. 4, an outside air introduction unit 110 may be attached to the air handling unit 20. The outside air introduction unit 110 has a third fan 111 and a third air volume detecting means 112. The outside air introduction unit 110 takes in the outside air OA from the outside of the target space 100 by the third fan 111 and blows it to the air handling unit 20. The third air volume detecting means 112 detects the air volume of the outside air OA sent to the air handling unit 20. The third air volume detecting means 112 transmits the detected value of the air volume of the outside air OA to the main controller 51. When the outside air OA is sent from the outside air introduction unit 110 to the air handling unit 20, the main controller 51 is configured to control so as to stop the third fan 111 when the first fan 21 is stopped. May be good. For the third air volume detecting means 112, for example, an air volume sensor, a wind speed sensor, or a differential pressure sensor can be used.

(4-2) Modification 1B
In the above embodiment, the case where the remote sensor 70 has the function of the temperature sensor has been described, but the remote sensor 70 has, for example, at least one function of the temperature sensor, the CO ₂ concentration sensor, and the humidity sensor. May be good. In other words, the remote sensor 70 can detect at least one of a temperature sensor, a CO ₂ concentration sensor and a humidity sensor as an environmental value. In the above embodiment, the temperature environment has been described as the environment handled by the air conditioning system 10, but the environment handled by the air conditioning system 10 may be at least one of temperature, CO ₂ concentration, and humidity.

When configured in this way, the plurality of sub-controllers 52 are each detected by the remote sensor 70 connected to the remote sensor 70 at least one of the temperature, CO ₂ concentration, and humidity of the target space 100. Receive the detected value as the environment value. Each sub-controller 52 holds the data of the set value to be detected as the value of the set environment. Each sub-controller 52 transmits to the main controller 51 the set value of at least one of these temperature, CO ₂ concentration and humidity as the value of the setting environment to be controlled. The main controller 51 determines the target air volume of each second unit 30 based on the set value according to the detection value of the corresponding remote sensor 70. The main controller 51 transmits the value of the target air volume to each sub controller 52. Each sub-controller 52 monitors the value of the environment by the remote sensor 70 while controlling each second fan 31 so that the supply air volume matches the target air volume. The characteristic operation of the air conditioning system 10 described above is performed using environmental values.

(5) Features (5-1)
In the air conditioning system 10 described above, the controller 50 sets the target value of the air volume of the fan unit 30 having the second fan 31 having at least one of the plurality of second fans 31 having a predetermined rotation speed or less. When the first condition that the amount of air sent from the air handling unit 20 is equal to or less than the threshold value is satisfied, the operation of the first fan 21 is stopped. Such stopping of operation of the first fan 21 makes it easier to reduce the supply air volume of the fan unit 30 having the second fan 31 having a predetermined rotation speed or less to be smaller than the target air volume value. By realizing the adjustment when the air volume is small by controlling the controller 50 in this way, it is not necessary to provide an extra device, or the device to be provided can be simplified, and the adjustment function when the air volume is small can be realized. The cost can be reduced.

(5-2)
In the air conditioning system 10 of the above embodiment, when the minimum rotation speed of the second fan 31 is used as the predetermined rotation speed, the supply air volume of the fan unit 30 having the second fan 31 having the minimum rotation speed or less is calculated from the value of the target air volume. Make it easier to reduce.

(5-3)
When the second condition is satisfied, the controller 50 of the air conditioning system 10 described above restarts the operation of the first fan that has been stopped by satisfying the first condition described above. Here, the second condition is that the environment of the target space 100 does not reach the setting environment set for at least one fan unit 30 among the plurality of fan units 30, and the supply of the one fan unit 30 is satisfied. It is a condition that the state in which the air volume does not reach the target air volume value continues for a predetermined time. By restarting the operation of the first fan 21 by the controller 50, the time for the supply air volume of the fan unit 30 to reach the target air volume value is shortened, and the environment of the target space 100 can be quickly reached to the set environment. Will be.

Although the embodiments of the present disclosure have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the present disclosure described in the claims. ..

10 Air conditioning system 20 Air handling unit 21 1st fan 22 Heat exchanger 30 Fan unit 31 2nd fan 40 Duct 50 Controller

Japanese Unexamined Patent Publication No. 10-253132

Claims (3)

An air handling unit (20) having a heat exchanger through which a heat medium flows and a first fan (21), and
A plurality of fan units (30) each having a second fan (31) that blows supply air into the target space, and
A duct (40) that distributes the supply air sent from the air handling unit by the first fan to the plurality of fan units, and
The controller (50) that controls the first fan and
With
In the controller, at least one of the plurality of second fans has a predetermined rotation speed or less, the air volume of the fan unit having the second fan having the predetermined rotation speed or less is equal to or more than the target value, and the air handling unit An air conditioning system (10) that stops the operation of the first fan when the condition that the amount of air delivered is equal to or less than the threshold value is satisfied. The predetermined rotation speed is the minimum rotation speed of the second fan.
The air conditioning system (10) according to claim 1. In the controller, the environment of the target space has not reached the setting environment set for at least one fan unit among the plurality of fan units, and the air volume of the at least one fan unit has reached the target value. When the non-existence state continues for a predetermined time, the operation of the first fan that has been stopped by satisfying the above conditions is restarted.
The air conditioning system (10) according to claim 1 or 2.

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