JP2020143853A - Air conditioning system and method of controlling the same - Google Patents

Abstract

To reduce initial costs by simplifying facilities as compared with employment of constitution in which the rotating speed of a pump is controlled based upon terminal differential pressure.SOLUTION: There is provided an air conditioning system comprising: a load device; a heat source machine which is connected to the load device through piping in which cold/hot water is circulated; a flow regulating valve which is provided in the piping and regulates the flow rate of the cold/hot water supplied to the load device; a variable speed pump which circulates the cold/hot water in the piping; a control part which controls the flow regulating valve and variable speed pump; a first transmission line which transmits first data for controlling the flow rate of the cold/hot water supplied to the load device from the control part to the flow regulating valve; and a second transmission line which transmits second data, as data used to control the pressure and flow rate of the whole cold/hot water circulated in the piping and corresponding to the first data, from the control part to the variable speed pump.SELECTED DRAWING: Figure 2

Description

The present invention relates to an air conditioning system and a control method thereof.

A differential pressure measuring means provided at each of the valves arranged at the inlets of a plurality of load devices and measuring the differential pressure between the water supply at the inlet of the load device and the return water at the outlet of the load device, and the differential pressure measuring means. Water supply control including a water supply control device that compares a plurality of measured differential pressures, identifies the terminal differential pressure at the end of the pipe, and controls the rotation speed of the pump and the opening degree of the bypass valve based on the terminal differential pressure. The system is known (eg, Patent Document 1).

JP-A-2009-30821

When adopting a configuration in which the rotation speed of the pump is controlled based on the terminal differential pressure, it is necessary to provide a differential pressure measuring means for each of the valves arranged at the inlets of a plurality of load devices, which complicates the equipment. The initial cost may be high.

An object of the present invention is to simplify the equipment and reduce the initial cost as compared with the case of adopting a configuration in which the rotation speed of the pump is controlled based on the terminal differential pressure.

For this purpose, the present invention adjusts the flow rate of the load device, the heat source device connected to the load device via the pipe through which the cold / hot water circulates, and the cold / hot water provided in the pipe and supplied to the load device. The flow control valve, the variable speed pump that circulates cold and hot water in the piping, the control unit that controls the flow control valve and the variable speed pump, and the first data that controls the flow rate of the cold and hot water supplied to the load equipment. Controls the first transmission line transmitted from the control unit to the flow control valve, and the second data that controls the pressure and flow rate of the entire cold and hot water circulated in the piping, which is the data corresponding to the first data. Provided is an air conditioning system including a second transmission line for transmitting from a unit to a variable speed pump.

The control unit may include a first control unit included in the load device and a second control unit included in the heat source machine. In that case, the air conditioning system further includes a communication line for communicating the first data from the first control unit to the second control unit, and the first transmission line is a flow control valve for transmitting the first data from the first control unit. The second transmission line may be one that transmits the second data from the second control unit to the variable speed pump.

The air conditioning system further includes a measuring unit for measuring the temperature, and the control unit generates the first data based on the difference between the preset set temperature and the measured temperature measured by the measuring unit. It may be.

The control unit may generate the opening degree of the flow rate adjusting valve as the first data. In that case, the control unit may generate the second data based on the opening degree of the flow rate adjusting valve, and further, the maximum value of the opening degree of the plurality of flow rate adjusting valves becomes the set value. As such, it may be one that produces a second piece of data.

The control unit may generate the rotation speed of the variable speed pump as the second data.

The control unit may control the flow rate adjusting valve to be forcibly opened based on the information indicating the load reduction in the load device.

The control unit may control the flow rate adjusting valve to be forcibly opened based on the information indicating the defrosting operation of the heat source machine.

Further, the present invention includes a load device, a heat source device connected to the load device via a pipe through which cold / hot water circulates, and a flow rate adjusting valve provided in the pipe to adjust the flow rate of the cold / hot water supplied to the load device. In an air conditioning system including a variable speed pump that circulates cold and hot water in a pipe and a control unit that controls a flow rate adjusting valve and the variable speed pump, the control unit controls the flow rate of the cold and hot water supplied to the load equipment. The second data, which is the step of transmitting the first data to the flow control valve and the data in which the control unit controls the pressure and flow rate of the entire cold / hot water circulated in the pipe, which is the data corresponding to the first data. Also provided is a method of controlling an air conditioning system, which comprises the step of transmitting the data to a variable speed pump.

In the control method of the air conditioning system, the control unit includes the first control unit of the load device and the second control unit of the heat source machine, and the first control unit transmits the first data to the flow control valve. It includes a step, a step in which the first control unit communicates the first data to the second control unit, and a step in which the second control unit transmits the second data to the variable speed pump. Good.

According to the present invention, the equipment can be simplified and the initial cost can be reduced as compared with the case of adopting a configuration in which the rotation speed of the pump is controlled based on the terminal differential pressure.

It is a figure which showed the system configuration example of the air-conditioning system in embodiment of this invention. It is a figure which showed the control configuration example in 1st Embodiment of the air-conditioning system in Embodiment of this invention. It is a flowchart which showed the operation example of the air conditioner control part included in the control configuration in 1st Embodiment of this invention. It is a flowchart which showed the operation example of the heat source machine control part included in the control structure in 1st Embodiment of this invention. (A) and (b) are diagrams showing the valve adjustment pressure and the theoretical water power in the terminal differential pressure constant control and the minimum differential pressure control, respectively. It is a figure which showed the control configuration example in the 2nd Embodiment of the air-conditioning system in the embodiment of this invention. It is a flowchart which showed the operation example of the air conditioner control part included in the control configuration in 2nd Embodiment of this invention. It is a flowchart which showed the operation example of the heat source machine control part included in the control structure in the 2nd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

[System configuration]
FIG. 1 is a diagram showing a system configuration example of the air conditioning system 1 according to the present embodiment. As shown in the figure, the system configuration of the air conditioning system 1 in the present embodiment includes air conditioners 10a to 10c, two-way valves 20a to 20c, room temperature controllers 30a to 30c, a heat source machine 40, and a variable speed pump 50. And the pipe 60. Further, the system configuration of the air conditioning system 1 in the present embodiment includes the first transmission lines 71a to 71c, the second transmission lines 72, the third transmission lines 73a to 73c, and the communication line 80. In the figure, air conditioners 10a to 10c, two-way valves 20a to 20c, room temperature controllers 30a to 30c, first transmission lines 71a to 71c, and third transmission lines 73a to 73c are shown. It may also be referred to as an air conditioner 10, a two-way valve 20, a room temperature controller 30, a first transmission line 71, and a third transmission line 73. Further, the figure shows three air conditioners 10, a two-way valve 20, a room temperature controller 30, a first transmission line 71, and a third transmission line 73, but these are only two or four or more. You may.

The air conditioner 10 is, for example, a device that air-conditions a room by using the heat of cold / hot water flowing through the pipe 60. The air conditioner 10 includes, for example, a fan coil unit (FCU) and an air handling unit (AHU). In the present embodiment, the air conditioner 10 is provided as an example of the load device.

The two-way valve 20 is provided in the pipe 60 and is a valve that adjusts the flow rate of cold and hot water to be distributed to the air conditioner 10. In the present embodiment, a two-way valve 20 is provided as an example of the flow rate adjusting valve.

The room temperature controller 30 is a device that measures the current room temperature (current room temperature) and adjusts the room temperature based on the deviation of the current room temperature from the set room temperature (set room temperature). In the present embodiment, the current room temperature is used as an example of the current temperature, the set room temperature is used as an example of the set temperature, and the deviation is used as an example of the difference. Further, as an example of the measuring unit for measuring the temperature, a room temperature controller 30 is provided.

The heat source machine 40 is a device that regulates the temperature of cold and hot water and distributes it through the pipe 60. The temperature of cold / hot water is lowered during cooling, and the temperature of cold / hot water is raised during heating. As the heat source machine 40, for example, an absorption chiller-heater, a heat pump type heat source machine, or the like may be used. Further, the heat source machine 40 may determine that the load on the air conditioner 10 has decreased. For example, if a flow rate sensor (not shown) is provided in the heat source machine 40 and the flow rate sensor detects that the flow rate of the cold / hot water has reached the lower limit flow rate, it may be determined that the load has decreased. Further, the heat source machine 40 may determine that the operation mode has been changed from the normal operation mode to the defrost operation mode.

The variable speed pump 50 is a pump that circulates cold and hot water in the pipe 60. The variable speed pump 50 is a rotary electric pump, and its flow rate is proportional to the number of rotations (that is, the rotation speed). The power source of the variable speed pump 50 is an electric motor such as an induction motor, and the rotation speed is controlled by using an inverter.

The pipe 60 is a pipe that connects the air conditioner 10 and the heat source machine 40, and circulates cold / hot water whose temperature has been adjusted by the heat source machine 40 while being supplied to the air conditioner 10.

The first transmission line 71 is a data line that connects the air conditioner 10 and the two-way valve 20 and enables data for controlling the flow rate of cold and hot water flowing through the air conditioner 10 to be transmitted from the air conditioner 10 to the two-way valve 20. is there. The first transmission line 71 is not limited to wired, and may be wireless. In the present embodiment, the first transmission line 71 is provided as an example of the first transmission line.

The second transmission line 72 is a data line that connects the heat source machine 40 and the variable speed pump 50 and enables data for controlling the pressure and flow rate of the entire cold / hot water to be transmitted from the heat source machine 40 to the variable speed pump 50. The second transmission line 72 is not limited to wired, and may be wireless. In the present embodiment, the second transmission line 72 is provided as an example of the second transmission line.

The third transmission line 73 is a data line that connects the air conditioner 10 and the room temperature controller 30 so that data indicating the deviation of the current room temperature from the set room temperature can be transmitted from the room temperature controller 30 to the air conditioner 10. The third transmission line 73 is not limited to wired, and may be wireless.

The communication line 80 is a data line that connects the air conditioner 10a to 10c and the heat source machine 40 and enables data communication between the air conditioner 10a to 10c and the heat source machine 40. In the following, the communication line 80 is a data line that connects the air conditioners 10a to 10c and the heat source unit 40 in a loop, but data that connects each of the air conditioners 10a to 10c and the heat source unit 40 on a one-to-one basis. It may be a line. When the communication line 80 is the latter data line, the communication line 80 is not limited to wired communication, and may be wireless.

[First Embodiment]
(Control configuration)
FIG. 2 is a diagram showing a control configuration example according to the first embodiment of the air conditioning system 1 of FIG. As shown in the figure, the control configuration in the first embodiment includes an air conditioner control unit 11a to 11c, a two-way valve 20a to 20c, a room temperature controller 30a to 30c, a heat source unit control unit 41, and a variable speed. Includes pump 50 and. Further, the control configuration of the air conditioning system 1 in the first embodiment includes the first transmission lines 71a to 71c, the second transmission line 72, the third transmission lines 73a to 73c, and the communication line 80. In the figure, the air conditioner control units 11a to 11c, the two-way valves 20a to 20c, the room temperature regulators 30a to 30c, the first transmission lines 71a to 71c, and the third transmission lines 73a to 73c are shown. If not, it may be referred to as an air conditioner control unit 11, a two-way valve 20, a room temperature controller 30, a first transmission line 71, or a third transmission line 73. Further, the figure shows three each of the air conditioner control unit 11, the two-way valve 20, the room temperature controller 30, the first transmission line 71, and the third transmission line 73, but these are only two or four or more. It may be.

Since the two-way valve 20, the room temperature controller 30, and the variable speed pump 50 have been described with reference to FIG. 1, the description is omitted. In the following, the air conditioner control unit 11, the heat source unit control unit 41, and the first transmission Only the line 71, the second transmission line 72, the third transmission line 73, and the communication line 80 will be described.

The air conditioner control unit 11 is a control unit included in the air conditioner 10, and is realized by a CPU (not shown) loading a program stored in a ROM (not shown) or the like into a RAM (not shown) and executing the program. To. The air conditioner control unit 11 receives the load request, that is, the deviation information indicating the deviation of the current room temperature from the set room temperature, from the room temperature controller 30 connected to itself via the third transmission line 73, and connects to itself. The opening degree of the two-way valve 20 is calculated. Here, the opening degree of the two-way valve 20 may be calculated by using a known method such as PID control. Then, the air conditioner control unit 11 transmits the calculated opening command (opening command) to the two-way valve 20 via the first transmission line 71. Specifically, if the load request is large, an opening command for increasing the opening is transmitted to the two-way valve 20, and if the load request is small, an opening command for decreasing the opening is transmitted to the two-way valve 20. .. Further, the air conditioner control unit 11 transmits the opening degree information including its own identification information and the opening degree to the heat source machine control unit 41 by flowing it through the communication line 80. In the present embodiment, the opening degree of the two-way valve 20 is used as an example of the first data. Further, as an example of the first control unit, an air conditioner control unit 11 is provided.

The heat source machine control unit 41 is a control unit included in the heat source machine 40, and is realized by a CPU (not shown) loading a program stored in a ROM (not shown) or the like into a RAM (not shown) and executing the program. To. The heat source machine control unit 41 receives opening information from the air conditioner control units 11a to 11c via the communication line 80, and based on this opening information, the heat source machine control unit 41 has the largest opening among the two-way valves 20a to 20c. The two-way valve 20 is specified, and the rotation speed of the variable speed pump 50 is calculated so that the opening degree of the specified two-way valve 20 becomes a set value (for example, about 90%). Here, the rotation speed of the variable speed pump 50 may be calculated by using a known method such as PID control. Then, the heat source machine control unit 41 transmits the calculated rotation speed command (rotation speed command) to the variable speed pump 50 via the second transmission line 72. Specifically, if the opening degree of the specified two-way valve 20 is smaller than the set value (for example, 90%), a rotation speed command for reducing the rotation speed is transmitted to the variable speed pump 50, and the specified two-way valve is used. If the opening degree of 20 is larger than the set value (for example, 90%), a rotation speed command for increasing the rotation speed is transmitted to the variable speed pump 50. In this embodiment, the rotation speed of the variable speed pump 50 is used as an example of the second data. Further, as an example of the second control unit, a heat source machine control unit 41 is provided.

The first transmission line 71 is a data line that connects the air conditioner control unit 11 and the two-way valve 20 so that an opening degree command can be transmitted from the air conditioner control unit 11 to the two-way valve 20.

The second transmission line 72 is a data line that connects the heat source machine control unit 41 and the variable speed pump 50 and enables transmission of a rotation speed command from the heat source machine control unit 41 to the variable speed pump 50.

The third transmission line 73 connects the air conditioner control unit 11 and the room temperature controller 30, and enables the room temperature controller 30 to transmit deviation information indicating the deviation of the current room temperature from the set room temperature to the air conditioner control unit 11. It is a data line.

The communication line 80 is a data line that connects the air conditioner control units 11a to 11c and the heat source machine control unit 41 so that the opening degree information can be transmitted from the air conditioner control units 11a to 11c to the heat source machine control unit 41. In reality, data can be transmitted from the heat source machine control unit 41 to the air conditioner control units 11a to 11c, but in the first embodiment, the heat source machine control unit 41 to the air conditioner control unit 11a Since no substantial data is transmitted to ~ 11c, this part of the communication line 80 is not shown.

(motion)
FIG. 3 is a flowchart showing an operation example of the air conditioner control unit 11 included in the control configuration according to the first embodiment. In the following, the air conditioner 10, the two-way valve 20, and the room temperature controller 30 refer to the air conditioner 10, the two-way valve 20, and the room temperature controller 30 corresponding to the air conditioner control unit 11 showing an operation example. It shall be.

As shown in the figure, first, the air conditioner control unit 11 receives the deviation information of the current room temperature from the set room temperature from the room temperature controller 30 (step 111).

Next, the air conditioner control unit 11 calculates the opening degree of the two-way valve 20 based on the deviation information received in step 111 (step 112). Then, an opening command for commanding the opening calculated in step 112 is transmitted to the two-way valve 20 (step 113).

Next, the air conditioner control unit 11 transmits the opening degree information including the identification information of the air conditioner 10 and the opening degree calculated in step 112 to the heat source machine control unit 41 (step 114), and ends the process.

FIG. 4 is a flowchart showing an operation example of the heat source machine control unit 41 included in the control configuration according to the first embodiment. In the following, a case where the air conditioner control units 11a to 11c are provided as the air conditioner control unit 11 as shown in FIG. 2 will be described.

As shown in the figure, first, the heat source machine control unit 41 receives the opening degree information from the air conditioner control units 11a to 11c (step 411). Since the opening degree information includes the identification information of each air conditioner 10, the heat source machine control unit 41 grasps the opening degree of the two-way valve 20 connected to each air conditioner 10 from the received opening degree information. You can do it.

Next, the heat source machine control unit 41 identifies the two-way valve 20 having the maximum opening among the two-way valves 20a to 20c based on the opening degree information received in step 411 (step 412). .. Then, the rotation speed of the variable speed pump 50 is calculated so that the opening degree of the specified two-way valve 20 becomes a set value (for example, 90%) (step 413).

Next, the heat source machine control unit 41 transmits a rotation speed command for commanding the rotation speed calculated in step 413 to the variable speed pump 50 (step 414), and ends the process.

(effect)
As a general method, constant end differential pressure control can be considered. However, in this method, since it is unclear which air conditioner system is required to supply how much pressure in actual operation, the terminal differential pressure of the design value must be constantly supplied. Therefore, a useless valve loss for adjusting the flow rate occurs.

On the other hand, in the minimum differential pressure control in the present embodiment, the supply pressure is controlled so as to keep the maximum opening degree of the valve in the plurality of air conditioner systems at about 90%. Therefore, the valve loss for adjusting the flow rate can be minimized.

Here, the difference in effect between the end differential pressure constant control and the minimum differential pressure control will be described using specific values.

5 (a) and 5 (b) are diagrams showing the valve adjustment pressure and the theoretical water power in the terminal differential pressure constant control and the minimum differential pressure control, respectively. In the figure, the systems # 1 to # 3 correspond to, for example, the systems of the air conditioners 10a to 10c in FIG.

Here, the design flow rate is 26.7 LPM (liters / minute) for all of the systems # 1 to # 3, and the total is 80 LPM. The design differential pressure is the differential pressure when all the two-way valves 20 are fully opened and cold / hot water is flowed at 26.7 LPM, and 50 kPa is set for all of the systems # 1 to # 3. It is assumed that the operation is actually started in this state, and the actual flow rate (actual flow rate) is 13 LPM for the system # 1, 20 LPM for the system # 2, and 7 LPM for the system # 3, for a total of 40 LPM. Then, the differential pressure (required differential pressure) required for each system is 12 kPa for system # 1, 28 kPa for system # 2, and 3 kPa for system # 3.

In this case, in the terminal differential pressure constant control, as shown in FIG. 5A, the variable speed pump 50 is controlled so as to always have the design differential pressure. That is, the control differential pressure of the variable speed pump 50 is 50 kPa. As a result, the pressure for adjusting the flow rate in the two-way valve 20 (valve adjustment pressure) is 38 kPa for the system # 1, 22 kPa for the system # 2, and 47 kPa for the system # 3. The theoretical water power of the variable speed pump 50 at this time is 33 W.

On the other hand, in the minimum differential pressure control, as shown in FIG. 5B, since the system # 2 has the largest load, the opening degree of the two-way valve 20 of this system is controlled to be 90%. That is, the control differential pressure of the variable speed pump 50 is 29 kPa. As a result, the pressure for adjusting the flow rate with the two-way valve 20 (valve adjustment pressure) becomes 1 kPa for the system # 2. The theoretical water power of the variable speed pump 50 at this time is 19 W.

(Modification example)
In the first embodiment, the air conditioner 10 has the air conditioner control unit 11, and the heat source machine 40 has the heat source machine control unit 41, but this is not the case. A control unit having both the function of the air conditioner control unit 11 and the function of the heat source machine control unit 41 may be provided independently of the air conditioner 10 and the heat source machine 40.

[Second Embodiment]
(Control configuration)
FIG. 6 is a diagram showing an example of a control configuration according to a second embodiment of the air conditioning system 1 of FIG. As shown in the figure, the control configuration in the second embodiment includes an air conditioner control unit 12a to 12c, a two-way valve 20a to 20c, a room temperature controller 30a to 30c, a heat source unit control unit 42, and a variable speed. Includes pump 50 and. Further, the control configuration of the air conditioning system 1 in the second embodiment includes the first transmission lines 71a to 71c, the second transmission line 72, the third transmission lines 73a to 73c, and the communication line 80. In the figure, air conditioner control units 12a to 12c, two-way valves 20a to 20c, room temperature controllers 30a to 30c, first transmission lines 71a to 71c, and third transmission lines 73a to 73c are shown, but these are distinguished. If not, it may be referred to as an air conditioner control unit 12, a two-way valve 20, a room temperature controller 30, a first transmission line 71, or a third transmission line 73. Further, the figure shows three each of the air conditioner control unit 12, the two-way valve 20, the room temperature controller 30, the first transmission line 71, and the third transmission line 73, but these are only two or four or more. It may be.

Since the two-way valve 20, the room temperature controller 30, and the variable speed pump 50 have been described with reference to FIG. 1, the description is omitted. In the following, the air conditioner control unit 12, the heat source unit control unit 42, and the first transmission Only the line 71, the second transmission line 72, the third transmission line 73, and the communication line 80 will be described.

The air conditioner control unit 12 is a control unit included in the air conditioner 10, and is realized by a CPU (not shown) loading a program stored in a ROM (not shown) or the like into a RAM (not shown) and executing the program. To. When the heat source machine control unit 42 receives the forced opening information including its own identification information and the information instructing to forcibly open the two-way valve 20 connected to itself via the communication line 80, A command for forcibly opening the two-way valve 20 (forced open command) is transmitted to the two-way valve 20 via the first transmission line 71. In addition, the air conditioner control unit 12 also performs the same operation as the air conditioner control unit 11 in the first embodiment. In the present embodiment, the air conditioner control unit 12 is provided as an example of the first control unit.

The heat source machine control unit 42 is a control unit included in the heat source machine 40, and is realized by a CPU (not shown) loading a program stored in a ROM (not shown) or the like into a RAM (not shown) and executing the program. To. When the heat source machine control unit 42 determines that the load on the air conditioner 10 has decreased, or when it determines that the operation mode of the heat source unit 40 has been changed from the normal operation mode to the defrost operation mode, all or part of the two. Instruct the air conditioner control unit 12 to forcibly open the side valve 20. Specifically, the air conditioner control unit 12 (hereinafter, referred to as “target two-way valve”) corresponding to the target two-way valve is determined by determining all or part of the two-way valves 20 (hereinafter referred to as “target two-way valves”) to be forcibly opened. The forced opening information including the identification information (referred to as "target air conditioner control unit") and the information instructing the target two-way valve to be forcibly opened is transmitted to the target air conditioner control unit by flowing it to the communication line 80. To do. In the present embodiment, an example of a control unit that controls the flow rate adjusting valve to be forcibly opened based on the information indicating the load reduction in the load device, or the flow rate adjustment based on the information indicating the defrosting operation of the heat source machine. A heat source machine control unit 42 is provided as an example of a control unit that controls the valve to be forcibly opened. Further, as an example of the second control unit, a heat source machine control unit 42 is provided. In addition, the heat source machine control unit 42 is the same as the heat source machine control unit 41 in the first embodiment for the air conditioner control unit 12 corresponding to the two-way valve 20 which is not determined as the target two-way valve. To perform the operation of.

The first transmission line 71 is a data line that connects the air conditioner control unit 12 and the two-way valve 20 so that an opening degree command can be transmitted from the air conditioner control unit 12 to the two-way valve 20.

The second transmission line 72 is a data line that connects the heat source machine control unit 42 and the variable speed pump 50 and enables transmission of a rotation speed command from the heat source machine control unit 42 to the variable speed pump 50.

The third transmission line 73 connects the air conditioner control unit 12 and the room temperature controller 30, and enables the room temperature controller 30 to transmit deviation information indicating the deviation of the current room temperature from the set room temperature to the air conditioner control unit 12. It is a data line.

The communication line 80 connects the air conditioner control units 12a to 12c and the heat source unit control unit 42, enables the opening degree information to be transmitted from the air conditioner control units 12a to 12c to the heat source unit control unit 42, and forcibly opens information. Is a data line that enables transmission from the heat source machine control unit 42 to the air conditioner control units 12a to 12c.

(motion)
FIG. 7 is a flowchart showing an operation example of the air conditioner control unit 12 included in the control configuration according to the second embodiment. In the following, the air conditioner 10, the two-way valve 20, and the room temperature controller 30 refer to the air conditioner 10, the two-way valve 20, and the room temperature controller 30 corresponding to the air conditioner control unit 12 showing an operation example. It shall be.

As shown in the figure, first, the air conditioner control unit 12 receives the deviation information of the current room temperature from the set room temperature from the room temperature controller 30 (step 121).

Next, the air conditioner control unit 12 determines whether or not the forced opening information has been received from the heat source unit control unit 42 (step 122). Since the forced opening information includes the identification information of each air conditioner 10, the air conditioner control unit 12 can grasp the forced opening information addressed to itself from the forced opening information flowing through the communication line 80. ..

As a result, if it is determined that the forced opening information has been received from the heat source machine control unit 42, the air conditioner control unit 12 transmits the forced opening command to the two-way valve 20 regardless of the deviation information received in step 121 ( Step 123).

On the other hand, if it is not determined that the forced opening information has been received from the heat source machine control unit 42, the air conditioner control unit 12 calculates the opening degree of the two-way valve 20 based on the deviation information received in step 121 (step). 124). Then, an opening command for commanding the opening calculated in step 124 is transmitted to the two-way valve 20 (step 125).

Next, the air conditioner control unit 12 obtains opening information including the identification information of the air conditioner 10 and the opening as a result of transmitting the forced opening command in step 123 or the opening calculated in step 124. It is transmitted to 42 (step 126), and the process ends.

FIG. 8 is a flowchart showing an operation example of the heat source machine control unit 42 included in the control configuration according to the second embodiment. In the following, a case where the air conditioner control units 12a to 12c are provided as the air conditioner control unit 12 as shown in FIG. 6 will be described.

As shown in the figure, first, the heat source machine control unit 42 receives the opening degree information from the air conditioner control units 12a to 12c (step 421). Since the opening degree information includes the identification information of each air conditioner 10, the heat source machine control unit 42 grasps the opening degree of the two-way valve 20 connected to each air conditioner 10 from the received opening degree information. You can do it.

Next, the heat source machine control unit 42 determines whether or not the cold / hot water flow rate has reached the lower limit flow rate (step 422). Then, if it is not determined that the cold / hot water flow rate has reached the lower limit flow rate, it is determined whether or not the heat source machine 40 has entered the defrost operation (step 423).

When it is determined in step 422 that the cold / hot water flow rate has reached the lower limit flow rate, or when it is determined in step 423 that the heat source machine 40 has been defrosted, the heat source machine control unit 42 is the target for issuing the forced opening command. The target two-way valve, which is the side valve 20, is determined (step 424). Here, the target two-way valve may be determined according to a predetermined rule. Then, by sending the forced opening information including the identification information of the target air conditioner control unit corresponding to the determined target two-way valve and the information instructing to forcibly open the target two-way valve to the communication line 80. , Transmit to the target air conditioner control unit (step 425).

Next, the heat source machine control unit 42 determines whether or not the target air conditioner control unit to which the forced opening information is transmitted in step 425 is all the air conditioner control units (step 426).

As a result, if it is not determined that the target air conditioner control unit that transmitted the forced opening information in step 425 is all the air conditioner control units, the heat source unit control unit 42 first starts from the opening degree information received in step 421. , The opening degree information received from the air conditioner control unit 12 other than the target air conditioner control unit is extracted (step 427). Next, the heat source machine control unit 42 identifies the two-way valve 20 having the maximum opening degree among the two-way valves 20 corresponding to the air conditioner control unit 12 other than the target air conditioner control unit (step 428). ). Then, the rotation speed of the variable speed pump 50 is calculated so that the opening degree of the specified two-way valve 20 becomes a set value (for example, 90%) (step 429). Next, the heat source machine control unit 42 transmits a rotation speed command for commanding the rotation speed calculated in step 429 to the variable speed pump 50 (step 430), and ends the process.

Further, even if it is not determined in step 423 that the heat source unit 40 has been defrosted, the target air conditioner control unit does not exist, so that the heat source unit control unit 42 describes all the air conditioner control units 12 from step 427 to 430 is executed and the process is terminated.

On the other hand, if it is determined in step 425 that the target air conditioner control unit that has transmitted the forced open information is all the air conditioner control units, there is no air conditioner control unit 12 that performs control as in the first embodiment. Therefore, the heat source machine control unit 42 ends the process without executing steps 427 to 430.

(effect)
In the second embodiment, the minimum flow rate is secured by forcibly opening all or part of the two-way valves 20 when the load is reduced and the flow rate of the cold / hot water reaches the lower limit flow rate. You can now do it. Further, by forcibly opening all or part of the two-way valves 20 when the heat source machine 40 is in the defrost operation, the defrost heat source flow rate can be secured.

(Modification example)
In the second embodiment, the air conditioner 10 has the air conditioner control unit 12, and the heat source unit 40 has the heat source unit control unit 42, but this is not the case. A control unit having both the function of the air conditioner control unit 12 and the function of the heat source machine control unit 42 may be provided independently of the air conditioner 10 and the heat source machine 40.

1 ... Air conditioner system, 10 ... Air conditioner, 11, 12 ... Air conditioner control unit, 20 ... Two-way valve, 30 ... Room temperature controller, 40 ... Heat source machine, 41, 42 ... Heat source machine control unit, 50 ... Variable speed pump , 60 ... piping, 71 ... first transmission line, 72 ... second transmission line, 73 ... third transmission line, 80 ... communication line

Claims (12)

With load equipment
A heat source machine connected to the load device via a pipe through which cold and hot water circulates.
A flow rate adjusting valve provided in the pipe and adjusting the flow rate of cold / hot water supplied to the load device,
A variable speed pump that circulates cold and hot water through the piping,
A control unit that controls the flow rate adjusting valve and the variable speed pump,
A first transmission line for transmitting first data for controlling the flow rate of cold / hot water supplied to the load device from the control unit to the flow rate adjusting valve, and
A second transmission for transmitting the second data, which is data for controlling the pressure and flow rate of the entire cold / hot water circulated in the pipe and is data corresponding to the first data, from the control unit to the variable speed pump. An air conditioning system characterized by having a wire. The control unit
The first control unit of the load device and
The air conditioning system according to claim 1, further comprising a second control unit included in the heat source machine. A communication line for communicating the first data from the first control unit to the second control unit is further provided.
The first transmission line transmits the first data from the first control unit to the flow rate adjusting valve.
The air conditioning system according to claim 2, wherein the second transmission line transmits the second data from the second control unit to the variable speed pump. Equipped with a measuring unit that measures temperature
The air conditioning system according to claim 1, wherein the control unit generates the first data based on a difference between a preset set temperature and a measurement temperature measured by the measurement unit. .. The air conditioning system according to claim 1, wherein the control unit generates an opening degree of the flow rate adjusting valve as the first data. The air conditioning system according to claim 5, wherein the control unit generates the second data based on the opening degree of the flow rate adjusting valve. The air conditioning system according to claim 6, wherein the control unit generates the second data so that the maximum value of the opening degree of the plurality of flow rate adjusting valves becomes a set value. The air conditioning system according to claim 1, wherein the control unit generates the rotation speed of the variable speed pump as the second data. The air conditioning system according to claim 1, wherein the control unit controls the flow rate adjusting valve to be forcibly opened based on information indicating a load reduction in the load device. The air conditioning system according to claim 1, wherein the control unit controls the flow rate adjusting valve to be forcibly opened based on information indicating a defrosting operation of the heat source machine. A load device, a heat source machine connected to the load device via a pipe through which cold / hot water circulates, a flow rate adjusting valve provided in the pipe and adjusting the flow rate of the cold / hot water supplied to the load device, and the said. In an air conditioning system including a variable speed pump that circulates cold and hot water in a pipe, a flow rate adjusting valve, and a control unit that controls the variable speed pump.
A step in which the control unit transmits first data for controlling the flow rate of cold / hot water supplied to the load device to the flow rate adjusting valve.
The step of transmitting the second data to the variable speed pump, which is the data in which the control unit controls the pressure and the flow rate of the entire cold / hot water circulated in the pipe and is the data corresponding to the first data. A method of controlling an air conditioning system, characterized in that it includes. The control unit
The first control unit of the load device and
Including the second control unit of the heat source machine
A step in which the first control unit transmits the first data to the flow rate regulating valve,
A step in which the first control unit communicates the first data to the second control unit.
The control method for an air conditioning system according to claim 11, wherein the second control unit includes a step of transmitting the second data to the variable speed pump.