JP2018112356A - Air Conditioning System - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the installation man-hour and the manufacturing cost for an air conditioning system by simplifying configurations for performing control over the air conditioning system.SOLUTION: A first air conditioner (50) and a second air conditioner (55) are connected to a heat source fluid circuit (20). The first air conditioner (50) regulates a temperature of air with a heat source fluid. The second air conditioner (55) performs a refrigeration cycle by exchanging heat of a refrigerant with the heat source fluid. A heat source-side controller (16) sets a circulation flow rate of the heat source fluid in the heat source fluid circuit (20) to a predetermined reference flow rate so that the first air conditioner (50) processes a part of a sensible heat load in a room. An air conditioning-side controller (17), on the other hand, regulates air conditioning capability of the second air conditioner (55) so that air in the room enters a predetermined target state.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air conditioning system that performs indoor air conditioning using a heat source fluid cooled or heated in a heat source device and a refrigerant in a refrigerant circuit that performs a refrigeration cycle.

  Patent Literature 1 discloses an air conditioner that performs indoor air conditioning by circulating heat source water between a heat source device and a load facility. In this air conditioner, the heat source water cooled or heated in the heat source device is supplied to the use side device such as a fan coil unit. The fan coil unit supplies air cooled or heated by heat source water into the room.

  Patent Document 2 discloses an air conditioner including a refrigerant circuit that performs a refrigeration cycle by exchanging heat between refrigerant and heat source water. This air conditioner supplies air cooled or heated by the refrigerant in the refrigerant circuit to the room.

  Patent Document 3 discloses an air conditioning system that performs indoor air conditioning using heat source water cooled or heated in a heat source device and refrigerant in a refrigerant circuit that performs a refrigeration cycle. The refrigerant circuit of this air conditioning system performs a refrigeration cycle by exchanging heat between the refrigerant and heat source water.

International Publication No. 2010/092916 Japanese Patent Laid-Open No. 08-210719 JP 2007-322024 A

  By the way, an air conditioner as disclosed in Patent Document 1 (that is, an air conditioner that performs air conditioning by heat source water itself) and an air conditioner as disclosed in Patent Document 2 (that is, a refrigerant circuit). It is conceivable to form one air conditioning system by combining with an air conditioner that performs air conditioning with the refrigerant. In this air conditioning system, a utilization side device such as a fan coil unit and a heat exchanger for exchanging heat of the refrigerant in the refrigerant circuit with the heat source water are connected to a circuit in which the heat source water circulates.

  In the air conditioning system described above, the air conditioning load in the room is processed by each of the air conditioner that performs air conditioning with the heat source water itself and the air conditioner that performs air conditioning with the refrigerant in the refrigerant circuit. Therefore, in this air conditioning system, it is conceivable to precisely control each of the two air conditioners described above according to the indoor air conditioning load.

  However, in order to precisely control each of the air conditioner that performs air conditioning by the heat source water itself and the air conditioner that performs air conditioning by the refrigerant in the refrigerant circuit, a complicated control system is required. In other words, a lot of information related to the operating condition and air conditioning load is transmitted and received between these two types of air conditioners, and further, complicated calculation processing based on the collected information is performed, and then an operation command to the air conditioner is given. It is necessary to determine the contents of the output and output the determined operation command. As a result, the configuration of the air conditioning system becomes complicated, which may increase the manufacturing cost of the air conditioning system.

  The present invention has been made in view of this point, and an object of the present invention is to provide an air conditioner having an air conditioner that performs air conditioning with the heat source fluid itself and an air conditioner that performs air conditioning with the refrigerant in the refrigerant circuit. Therefore, the manufacturing cost of the air conditioning system is reduced by simplifying the configuration for performing the control.

  The first invention cools or heats the heat source fluid circuit (20) in which the heat source fluid circulates and the heat source fluid of the heat source fluid circuit (20) so that the temperature of the heat source fluid becomes a predetermined target temperature. Heat source device (15), a first air conditioner (50) for supplying air cooled or heated by the heat source fluid of the heat source fluid circuit (20) to the room, and a refrigerant as the heat source fluid circuit (20 And a second air conditioner (55) for supplying air cooled or heated by the refrigerant into the room, and having a refrigerant circuit (60) that performs heat exchange with the heat source fluid of Targets harmony systems. Then, the circulation flow rate of the heat source fluid in the heat source fluid circuit (20) is set to a predetermined reference flow rate so that the first air conditioner (50) processes a part of the sensible heat load in the room. A heat source side controller (16) and an air conditioning side controller (17) for adjusting the air conditioning capacity of the second air conditioner (55) so that the indoor air state becomes a predetermined target state It is.

  In 1st invention, a 1st air conditioner (50) and a 2nd air conditioner (55) are provided in an air conditioning system (10). The first air conditioner (50) and the second air conditioner (55) each perform air conditioning in the room by supplying air to the room.

  In the first invention, the heat source side controller (16) sets the circulation flow rate of the heat source fluid in the heat source fluid circuit (20) to a predetermined reference flow rate. That is, the heat source side controller (16) does not perform an operation of precisely increasing or decreasing the circulation flow rate of the heat source fluid, but performs an operation of maintaining the circulation flow rate of the heat source fluid at the reference flow rate for a certain period of time. The reference flow rate is determined in advance so that the first air conditioner (50) processes a part of the sensible heat load in the room.

  In the first invention, the air-conditioning controller (17) is configured to control the second air conditioner (55) so that the indoor air state (for example, the temperature and relative humidity of the indoor air) is in a predetermined target state. Adjust the air conditioning capacity. As described above, a part of the sensible heat load in the room is processed by the first air conditioner (50). For this reason, a 2nd air conditioner (55) processes the part which the 1st air conditioner (50) was not able to process among indoor sensible heat loads, and an indoor latent heat load. As a result, the indoor air conditioning load is processed by the first air conditioner (50) and the second air conditioner (55).

  According to a second aspect of the present invention, in the first aspect of the present invention, the first air conditioner (50) includes an air conditioning heat exchanger (51) that exchanges heat between the heat source fluid of the heat source fluid circuit (20) and air. The heat source side heat exchanger (63) for exchanging heat between the refrigerant and the heat source fluid of the heat source fluid circuit (20) is provided in the refrigerant circuit (60) of the second air conditioner (55). In the heat source fluid circuit (20), the heat source side heat exchange of the second air conditioner (55) is arranged downstream of the air conditioning heat exchanger (51) of the first air conditioner (50). A vessel (63) is arranged.

  In the second invention, the heat source fluid flowing through the heat source fluid circuit (20) exchanges heat with air in the air conditioning heat exchanger (51) of the first air conditioner (50), and then the second air conditioner (55 ) In the heat source side heat exchanger (63) to exchange heat with the refrigerant in the refrigerant circuit (60). When both the first air conditioner (50) and the second air conditioner (55) perform cooling, the heat source fluid cooled in the heat source device (15) absorbs heat from the air in the air conditioner heat exchanger (51). Then, the temperature rises, and then the temperature further rises by absorbing heat from the refrigerant in the heat source side heat exchanger (63). On the other hand, when both the first air conditioner (50) and the second air conditioner (55) perform heating, the heat source fluid heated in the heat source device (15) is air-conditioned in the heat exchanger for air conditioning (51). The temperature is lowered by releasing heat to the heat source, and then the temperature is further lowered by releasing heat to the refrigerant in the heat source side heat exchanger (63).

  In a third aspect based on the second aspect, the heat source fluid circuit (20) includes a bypass pipe (24a, 24b) that bypasses the air conditioner heat exchanger (51), and the heat source fluid is used for the air conditioner. A first flow state that flows into the heat source side heat exchanger (63) after passing through the heat exchanger (51), and the heat source side heat exchanger (63 after the heat source fluid passes through the bypass pipes (24a, 24b). ) And a switching mechanism (25a, 25b) for switching between the second flow state flowing into.

  In the third invention, the flow path of the heat source fluid is switched between the first flow state and the second flow state by the switching mechanism (25a, 25b) of the heat source fluid circuit (20). In the first distribution state, the heat source fluid passes through the air conditioner heat exchanger (51) of the first air conditioner (50) and then passes through the heat source side heat exchanger (63) of the second air conditioner (55). pass. On the other hand, in the second circulation state, the heat source fluid passes through the bypass pipes (24a, 24b) without passing through the air conditioner heat exchanger (51) of the first air conditioner (50), and then the second air conditioner. Pass the heat source side heat exchanger (63) of the machine (55). In the second circulation state, the first air conditioner (50) is in a stopped state in which indoor air conditioning is not performed, and the second air conditioner (55) performs indoor air conditioning.

  In a fourth aspect based on any one of the first to third aspects, the first air conditioner (50) exchanges the indoor air sucked from the room with the heat source fluid and supplies it to the room. On the other hand, the second air conditioner (55) has the refrigerant circuit (60) and is configured to supply the indoor air sucked from the room into the room after exchanging heat with the refrigerant. And an outside air processing unit (70) configured to supply outdoor air sucked from the outside into the room after adjusting the temperature and humidity of the outdoor air. is there.

  In 4th invention, the external air processing unit (70) of a 2nd air conditioner (55) processes the external air load which is a part of air-conditioning load. Further, the portion of the indoor air conditioning load that is not processed by the outside air processing unit (70) is processed by the inside air processing unit (56) of the first air conditioner (50) and the second air conditioner (55).

  In the present invention, the heat source side controller (16) sets the circulation flow rate of the heat source fluid in the heat source fluid circuit (20) to a predetermined reference flow rate. That is, the heat source side controller (16) performs an operation of maintaining the circulation flow rate of the heat source fluid at the reference flow rate for a certain period of time (that is, a relatively simple control operation). For this reason, the configuration of the heat source side controller (16) is very simple. In a state where the circulation flow rate of the heat source fluid in the heat source fluid circuit (20) is set to the reference flow rate, a part of the sensible heat load in the room is processed by the first air conditioner (50). On the other hand, since the air-conditioning controller (17) adjusts the air-conditioning capacity of the second air conditioner (55), the portion of the indoor air-conditioning load that could not be processed by the first air conditioner (50) Processed by air conditioner (55).

  Thus, in the air conditioning system (10) of the present invention, the first air conditioner (50) and the second air conditioner (55) are used while using the heat source side controller (16) with a simple configuration. The air conditioning load in the room can be processed. Therefore, according to the present invention, the configuration for controlling the air conditioning system (10) can be simplified without impairing the function of the air conditioning system (10) for reliably processing the air conditioning load in the room. As a result, it is possible to reduce the man-hours required for installing the air conditioning system (10) and the manufacturing cost of the air conditioning system (10).

  In the air conditioning system (10) of the present invention, the first air conditioner (50) processes indoor sensible heat loads. For this reason, in the operation in which the first air conditioner (50) cools the air, the temperature of the heat source fluid supplied to the first air conditioner (50) can be set to a temperature higher than the dew point of the room air. Therefore, according to the present invention, it is possible to reduce energy consumption of the heat source device (15).

  In the second invention, in the heat source fluid circuit (20), the heat source side heat exchanger of the second air conditioner (55) is disposed downstream of the air conditioner heat exchanger (51) of the first air conditioner (50). (63) is arranged. That is, the heat source fluid flowing through the heat source fluid circuit (20) exchanges heat with air in the air conditioner heat exchanger (51), and then exchanges heat with the refrigerant in the refrigerant circuit (60) in the heat source side heat exchanger (63). To do. For this reason, compared with the case where the heat source fluid is individually supplied from the heat source device (15) to the air conditioning heat exchanger (51) and the heat source side heat exchanger (63), the heat medium sent from the heat source device (15). The temperature difference between the fluid and the heat source fluid returning to the heat source device (15) can be enlarged. As a result, while maintaining the amount of heat transferred by the heat source fluid, the circulation flow rate of the heat source fluid in the heat source fluid circuit (20) can be reduced, and the power required to circulate the heat source fluid can be reduced.

  In the third aspect of the invention, the switching mechanism (25a, 25b) switches the flow path of the heat source fluid, so that both the first air conditioner (50) and the second air conditioner (55) adjust the indoor air condition. It is possible to switch between an operation state to be performed and an operation state in which only the second air conditioner (55) performs indoor air conditioning. Therefore, according to this invention, it becomes possible to select the operating state of the air conditioning system (10) according to the indoor air conditioning load, and the air conditioning system (10) can process the indoor air conditioning load without excess or deficiency. Is possible.

FIG. 1 is a piping system diagram showing the configuration of the air conditioning system of the first embodiment. FIG. 2 is a schematic configuration diagram of an outside air processing unit according to the first embodiment. FIG. 3 is a piping diagram illustrating a configuration of an air conditioning system according to a modification of the first embodiment. FIG. 4 is a piping diagram showing the configuration of the air conditioning system of the second embodiment.

  Embodiments of the present invention will be described in detail with reference to the drawings. Note that the embodiments and modifications described below are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1
The first embodiment will be described. This embodiment is an air conditioning system (10) that performs indoor air conditioning.

  As shown in FIG. 1, the air conditioning system (10) includes a first subsystem (11a), a second subsystem (11b), a heat source water circuit (20), a heat source device (15), and a heat source side. And a controller (16). The number of subsystems (11a, 11b) provided in the air conditioning system (10) is merely an example.

  Each of the first subsystem (11a) and the second subsystem (11b) includes a fan coil unit (50) that is a first air conditioner, a second air conditioner (55), and an air conditioning side controller (17 ). These two subsystems (11a, 11b) are similarly configured. The first subsystem (11a) performs air conditioning of the first indoor space (100a), and the second subsystem (11b) performs air conditioning of the second indoor space (100b).

  The second air conditioner (55) of each subsystem (11a, 11b) includes an inside air processing unit (56) and an outside air processing unit (70). The number of fan coil units (50), inside air processing units (56), and outside air processing units (70) provided in each subsystem (11a, 11b) may be one or plural. It may be.

<Fan coil unit>
As shown in FIG. 1, the fan coil unit (50) includes an air conditioning heat exchanger (51). The heat exchanger for air conditioning (51) is a cross fin type fin-and-tube heat exchanger. The air conditioner heat exchanger (51) is connected to the heat source water circuit (20), and heat-exchanges the heat source water of the heat source water circuit (20) with air. Although not shown, the fan coil unit (50) includes a fan. The fan coil unit (50) sucks air from the indoor space (100a, 100b), exchanges heat with the heat source water in the air conditioning heat exchanger (51), and then into the indoor space (100a, 100b). It is configured to blow out.

<Inside air treatment unit>
As shown in FIG. 1, the inside air processing unit (56) includes one heat source side unit (57) and a plurality of usage side units (58). In the inside air processing unit (56), the refrigerant circuit (60) is formed by connecting the heat source side unit (57) and the use side unit (58) with a communication pipe. The number of heat source side units (57) and utilization side units (58) is merely an example.

  The refrigerant circuit (60) includes a compressor (61), a four-way switching valve (62), a heat source side heat exchanger (63), an expansion valve (64), and a use side heat exchanger (65). Is provided. In the refrigerant circuit (60), the compressor (61) has a discharge pipe connected to the first port of the four-way switching valve (62) and a suction pipe connected to the second port of the four-way switching valve (62). . In the refrigerant circuit (60), the heat source side heat exchanger (63), the expansion valve (64), and the use side heat are sequentially arranged from the third port to the fourth port of the four-way switching valve (62). An exchanger (65) is arranged. A plurality of usage-side heat exchangers (65) are provided in the refrigerant circuit (60). In the refrigerant circuit (60), the plurality of usage-side heat exchangers (65) are connected in parallel to each other.

  The compressor (61) is a hermetic scroll compressor. The four-way switching valve (62) includes a first state (state indicated by a solid line in FIG. 1) in which the first port communicates with the third port and the second port communicates with the fourth port; This is a switching valve that switches to a second state (state indicated by a broken line in FIG. 1) in which the port communicates with the fourth port and the second port communicates with the third port. The expansion valve (64) is an electronic expansion valve (64) having a variable opening.

  The heat source side heat exchanger (63) is a plate heat exchanger in which a plurality of primary side flow paths (63a) and a plurality of secondary side flow paths (63b) are formed. The heat source side heat exchanger (63) has a primary side flow path (63a) connected to the heat source water circuit (20) and a secondary side flow path (63b) connected to the refrigerant circuit (60). The heat source side heat exchanger (63) exchanges heat between the refrigerant flowing through the secondary side flow path (63b) and the heat source water flowing through the primary side flow path (63a). On the other hand, the use side heat exchanger (65) is a cross fin type fin-and-tube heat exchanger. The use side heat exchanger (65) causes the refrigerant in the refrigerant circuit (60) to exchange heat with air.

  The compressor (61), the four-way switching valve (62), the heat source side heat exchanger (63), and the expansion valve (64) are accommodated in the heat source side unit (57). On the other hand, one use side heat exchanger (65) is accommodated in each use side unit (58). Although not shown, each user side unit (58) includes a fan. Each usage side unit (58) sucks air from the indoor space (100a, 100b), exchanges heat with the refrigerant in the usage side heat exchanger (65), and then into the indoor space (100a, 100b). It is configured to blow out.

<Outside air treatment unit>
As shown in FIG. 2, the outside air processing unit (70) includes a casing (71), a total heat exchanger (81), an air supply fan (83), an exhaust fan (84), and a humidifying element (82). And.

  An air supply passage (72) and an exhaust passage (73) are formed in the casing (71). The casing (71) has an air supply port (74), an exhaust port (75), an outside air suction port (76), and an inside air suction port (77). The inlet passage (72) has an inlet end connected to the outside air inlet (76) and an outlet end connected to the inlet port (74). The exhaust passage (73) has an inlet end connected to the inside air suction port (77) and an outlet end connected to the exhaust port (75).

  The total heat exchanger (81) is disposed across both the air supply passage (72) and the exhaust passage (73). The total heat exchanger (81) is a heat exchanger that exchanges heat and moisture between outdoor air flowing through the air supply passage (72) and indoor air flowing through the exhaust passage (73).

  In the air supply passage (72), an air supply fan (83) and a humidifying element (82) are disposed downstream of the total heat exchanger (81). The humidifying element (82) is a member for humidifying air using a moisture permeable membrane or a non-woven fabric, and constitutes a so-called vaporizing humidifier. On the other hand, in the exhaust passage (73), an exhaust fan (84) is disposed downstream of the total heat exchanger (81).

  As shown in FIG. 1, the air supply port (74) is connected to the air outlet unit (91) via a duct, and communicates with the indoor space (100a, 100b) via the air outlet unit (91). The room air suction port (77) is connected to the suction port unit (92) via a duct, and communicates with the indoor space (100a, 100b) via the suction port unit (92). Each of the exhaust port (75) and the outside air suction port (76) communicates with the outdoor space via a duct (not shown).

<Air conditioning controller>
The air conditioning controller (17) is configured to control the operation of the inside air processing unit (56). Although not shown, the air conditioning controller (17) includes electronic components such as a CPU and a memory. The air conditioning controller (17) performs a predetermined control operation based on a program recorded in the memory.

  Specifically, the air conditioning side controller (17) adjusts the operating capacity of the compressor (61) and the opening of the expansion valve (64) using various data. Examples of data used by the air conditioning side controller (17) include measured values of the temperature of the indoor air sucked into the use side unit (58), the set temperature of the indoor space (100a, 100b), the heat source side heat exchanger ( 63) The measured value of the temperature of the heat source water supplied to the primary side flow path (63a), the measured value of the temperature and pressure of the refrigerant in each part of the refrigerant circuit (60), and the like are increased. The air conditioning controller (17) performs an operation of switching the four-way switching valve (62). Furthermore, the air conditioning side controller (17) may be configured to perform an operation of adjusting the air flow rate of a fan provided in the use side unit (58).

  The air conditioning controller (17) controls the operation of the inside air processing unit (56) so that the air state of the indoor space (100a, 100b) becomes a predetermined target state. The target state is represented by a target value of one or more physical quantities (for example, temperature, relative humidity, etc.) indicating the air state. The air-conditioning side controller (17) controls the operating capacity of the compressor (61) and the expansion valve (64 so that one or more physical quantities indicating the state of air in the indoor space (100a, 100b) become the target values. ) And other adjustments.

  For example, the air conditioning side controller (17) sets the target value of the refrigerant evaporation temperature or condensation temperature in the use side heat exchanger (65) of the inside air processing unit (56), and sets the air conditioning load ( Specifically, in consideration of the set value of the room temperature and a physical quantity such as an actual measurement value, the COP (coefficient of performance) of the inside air processing unit (56) is determined to be the highest. Then, the air conditioning side controller (17) controls the operating capacity of the compressor (61), the expansion valve so that the measured value of the refrigerant evaporation temperature or the condensation temperature in the use side heat exchanger (65) becomes the target value. Control the opening of (64).

<Heat source water circuit>
The heat source water circuit (20) is a circuit through which heat source water that is a heat source fluid circulates, and constitutes a heat source fluid circuit.

  As shown in FIG. 1, the heat source water circuit (20) includes a feed pipe (30) and a return pipe (40). The feed pipe (30) includes one collecting pipe (31) and two (that is, the same number as the subsystems (11a, 11b)) branch pipes (32a, 32b). The return pipe (40) includes one collecting pipe (41) and two (that is, the same number as the subsystems (11a, 11b)) branch pipes (42a, 42b). The heat source water circuit (20) is provided with two use-side bypass pipes (24a, 24b) and three-way valves (25a, 25b) (that is, the same number as the subsystems (11a, 11b)). Yes.

  In the feed pipe (30), the start end of the collecting pipe (31) is connected to the heat source device (15). One end of each branch pipe (32a, 32b) is connected to the end of the collecting pipe (31). The other end of each branch pipe (32a, 32b) is connected to the air conditioning heat exchanger (51) of the fan coil unit (50) of the corresponding subsystem (11a, 11b). That is, the other end of the first branch pipe (32a) is connected to the inflow end of the air conditioning heat exchanger (51) of the first subsystem (11a), and the other end of the second branch pipe (32b) is The air conditioner heat exchanger (51) of the second subsystem (11b) is connected to the inflow end.

  In the return pipe (40), the end of the collecting pipe (41) is connected to the heat source device (15). The collecting pipe (41) has one end of each branch pipe (42a, 42b) connected to the starting end thereof. The other end of each branch pipe (42a, 42b) is connected to the air conditioning heat exchanger (51) of the fan coil unit (50) of the corresponding subsystem (11a, 11b). That is, the other end of the first branch pipe (42a) is connected to the outflow end of the air conditioning heat exchanger (51) of the first subsystem (11a), and the other end of the second branch pipe (42b) is And connected to the outflow end of the heat exchanger (51) for air conditioning of the second subsystem (11b).

  The branch pipes (42a, 42b) of the return pipe (40) are connected to the heat source side heat exchanger (63) of the inside air processing unit (56) of the corresponding subsystem (11a, 11b). That is, the primary branch flow path (63a) of the heat source side heat exchanger (63) of the first subsystem (11a) is connected to the first branch pipe (42a), and the second branch pipe (42b) is connected to the first branch pipe (42a). Is connected to the primary flow path (63a) of the heat source side heat exchanger (63) of the second subsystem (11b).

  Each branch pipe (42a, 42b) of the return pipe (40) is provided with one three-way valve (25a, 25b). In each branch pipe (42a, 42b), a three-way valve (25a, 25b) and a heat source side heat exchanger (63) are arranged in order from one end to the other end. In each branch pipe (42a, 42b), the three-way valve (25a, 25b) has a first port connected to the primary flow path (63a) of the heat source side heat exchanger (63) and a second port connected to the fan. It is connected to the heat exchanger (51) for air conditioning of the coil unit (50).

  A use side bypass pipe (24a, 24b) is connected to the three-way valve (25a, 25b) of each branch pipe (42a, 42b) of the return pipe (40). In the three-way valve (25a) of the first branch pipe (42a), one end of the first user-side bypass pipe (24a) is connected to the third port. The other end of the first usage-side bypass pipe (24a) is connected to the first branch pipe (32a) of the feed pipe (30). On the other hand, in the three-way valve (25b) of the second branch pipe (42b), one end of the second usage-side bypass pipe (24b) is connected to the third port. The other end of the second usage-side bypass pipe (24b) is connected to the second branch pipe (32b) of the feed pipe (30).

  The three-way valve (25a, 25b) has a first state in which the first port communicates with the second port and is blocked from the third port (a state indicated by a solid line in FIG. 1), and the first port is in the first state. 3 is a switching valve that communicates with the third port and switches to a second state (state indicated by a broken line in FIG. 1) that is blocked from the second port. The three-way valves (25a, 25b) constitute a switching mechanism for switching between a first flow state and a second flow state, which will be described later.

  The heat source water circuit (20) is provided with a heat source water pump (21), a heat source side bypass pipe (22), and a flow rate control valve (23). A plurality of heat source water pumps (21) are provided in the heat source water circuit (20). The plurality of heat source water pumps (21) are provided in the collecting pipe (31) of the feed pipe (30). The plurality of heat source water pumps (21) are connected in parallel to each other. One end of the heat source side bypass pipe (22) is connected to the downstream side of the heat source water pump (21) in the collecting pipe (31) of the feed pipe (30), and the other end is the collecting pipe (41) of the return pipe (40). It is connected to the. The flow rate control valve (23) is a variable opening control valve, and is provided in the heat source side bypass pipe (22).

<Heat source equipment>
The heat source device (15) is configured to adjust the temperature of the heat source water flowing in from the return pipe (40) and send the heat source water whose temperature has been adjusted to the feed pipe (30). The heat source device (15) cools or heats the heat source water flowing from the return pipe (40), and sends the heat source water that has been cooled or heated to a predetermined target temperature to the feed pipe (30). To do. The heat source device (15) of this embodiment is composed of a plurality of chiller devices connected in parallel to each other. The chiller device constituting the heat source device (15) performs a refrigeration cycle. The chiller apparatus selectively performs an operation for cooling the heat source water with the refrigerant and an operation for heating the heat source water with the refrigerant.

  The heat source device (15) may be constituted by a refrigeration apparatus that performs a refrigeration cycle to cool the heat source water and a boiler that heats the heat source water by the combustion heat of fuel. The heat source equipment (15) consists of a ground heat exchanger that cools or heats the heat source water using geothermal heat, and a waste heat recovery device that heats the heat source water using exhaust heat from a fuel cell, etc. May be.

<Heat source side controller>
The heat source side controller (16) is configured to set the circulation flow rate of the heat source water in the heat source water circuit (20) to a predetermined reference flow rate. Although not shown, the heat source side controller (16) includes electronic components such as a CPU and a memory. The heat source side controller (16) performs a predetermined control operation based on a program recorded in the memory.

  The heat source side controller (16) is configured to adjust the number of operating heat source water pumps (21) so that the circulation flow rate of the heat source water in the heat source water circuit (20) becomes the reference flow rate. Specifically, the heat source side controller (16) stores in advance a reference flow rate corresponding to a calendar. The heat source side controller (16) stores in advance a reference flow rate used for each day of the year, for example. When the air conditioning system (10) is started, the heat source side controller (16) reads the reference flow rate corresponding to the day from the memory. Then, the heat source side controller (16) determines the number of operating heat source water pumps (21) corresponding to the reference flow rate read from the memory, and operates the determined number of heat source water pumps (21).

  The “circulation flow rate of the heat source water in the heat source water circuit (20)” is “the total value of the flow rates of the heat source water supplied to each subsystem (11a, 11b)”. Therefore, the heat source side controller (16) is configured so that the “total value of the flow rate of the heat source water supplied to each subsystem (11a, 11b)” becomes the “reference flow rate read from the memory”. 21) The number of operating units (that is, the number of heat source water pumps (21) to be operated) is determined. When the flow rate adjustment valve (23) of the heat source side bypass pipe (22) is closed, the “circulation flow rate of the heat source water in the heat source water circuit (20)” is equal to the discharge flow rate of the heat source water pump (21).

  Thus, the heat source side controller (16) is determined according to the reference flow rate, not the operation of controlling the heat source water pump (21) using the measured value of the sensor provided in the air conditioning system (10). The operation (namely, comparatively simple control operation) which operates the heat source water pumps (21) of a certain number is performed. Note that the heat source side controller (16) may divide a year into a plurality of periods, for example, every 10 days or every month, and store a reference flow rate used in each of these periods in advance.

  The reference flow rate is determined in advance so that the fan coil unit (50) processes part of the sensible heat load (for example, part or all of the housing load) of the indoor space (100a, 100b). Here, the air conditioning load of the indoor space (100a, 100b) is the sum of the internal load and the housing load. The internal load is a load caused by heat generation of a human body, a lighting device, an OA device, and the like, and varies greatly depending on a use situation of a room to be air-conditioned. For this reason, it is difficult to predict the internal load in advance. On the other hand, the housing load is a heat load determined by the location of the building (specifically, the average weather conditions such as the average temperature of the location), the structure of the building, the physical properties of the building material, etc., and is relatively accurate in advance. Can be predicted. Therefore, in the present embodiment, the circulation flow rate of the heat source water that allows at least a part of the housing load that is easy to predict to be processed by the fan coil unit (50) is used as the reference flow rate.

  The heat source side controller (16) may adjust the number of operating chiller devices constituting the heat source device (15) in addition to adjusting the number of operating heat source water pumps (21).

-Driving action-
The operation of the air conditioning system (10) will be described. The air conditioning system (10) selectively performs a cooling operation, a heating operation, and a cooling / heating mixed operation. In addition, the temperature of the heat source water shown below is only an example.

  In the cooling season from late spring to early autumn, the heat source device (15) supplies, for example, about 20 ° C. heat source water (medium temperature water for cooling) to the subsystems (11a, 11b). On the other hand, in the heating season from late autumn to early spring, the heat source device (15) supplies, for example, about 30 ° C. heat source water (medium temperature water for heating) to the subsystems (11a, 11b).

<Cooling operation>
The cooling operation is an operation in which each subsystem (11a, 11b) cools the indoor space (100a, 100b). In each sub-system (11a, 11b) during cooling operation, the fan coil unit (50) processes the sensible heat load in the room, and the indoor air processing unit (56) processes the sensible heat load and the latent heat load in the room. The processing unit (70) processes the sensible heat load and the latent heat load in the room.

  In the cooling operation, the heat source device (15) supplies heat source water (medium temperature water for cooling) of about 20 ° C. to the subsystems (11a, 11b). In the cooling operation, the three-way valve (25a, 25b) corresponding to each subsystem (11a, 11b) is set to the first state, and the four-way switching valve (56) of the internal air processing unit (56) of each subsystem (11a, 11b) 62) is set to the first state.

  In the cooling operation, the three-way valves (25a, 25b) are in the first state. For this reason, the distribution path of the heat source water in the heat source water circuit (20) is in the first distribution state. That is, the part corresponding to each subsystem (11a, 11b) in the heat source water circuit (20) (that is, the branch pipe (32a, 42a) corresponding to the first subsystem (11a) and the second subsystem (11b) In the branch pipes (32b, 42b) corresponding to), the heat source side heat exchanger (63) of the inside air processing unit (56) is arranged downstream of the air conditioning heat exchanger (51) of the fan coil unit (50). The

  The heat source water sent from the heat source device (15) to the feed pipe (30) is distributed to each subsystem (11a, 11b) through the branch pipe (32a, 32b) of the feed pipe (30). In each subsystem (11a, 11b), the heat source water supplied through the feed pipe (30) flows into the air conditioner heat exchanger (51) of the fan coil unit (50). As will be described later, in the air conditioning heat exchanger (51) of the fan coil unit (50), the heat source water absorbs heat from the air, and the temperature rises to about 23 ° C.

  In each subsystem (11a, 11b), the heat source water flowing out from the heat exchanger for air conditioning (51) passes through the three-way valve (25a, 25b), and the heat source side heat exchanger (63) of the inside air treatment unit (56) Flow into. As will be described later, in the refrigerant circuit (60) of the inside air processing unit (56), a refrigeration cycle in which the heat source side heat exchanger (63) functions as a condenser is performed. For this reason, the heat source water flowing into the primary side flow path (63a) of the heat source side heat exchanger (63) absorbs heat from the refrigerant in the refrigerant circuit (60), and the temperature rises to about 30 ° C. The heat source water flowing out from the heat source side heat exchanger (63) passes through the branch pipes (42a, 42b) and the collecting pipe (41) of the return pipe (40) in order, and then flows into the heat source device (15).

  In each subsystem (11a, 11b), the fan coil unit (50) supplies the air sucked from the indoor space (100a, 100b) to the air conditioner heat exchanger (51). In the air conditioner heat exchanger (51), the indoor air sucked into the fan coil unit (50) is cooled by exchanging heat with the heat source water. Usually, the dew point of room air is lower than 20 ° C. (that is, the temperature of the warm water for cooling). For this reason, in the heat exchanger for air conditioning (51), condensation does not occur, and only the sensible heat load process is performed. That is, in the heat exchanger for air conditioning (51), the temperature of the air decreases, while the amount of moisture contained in the air (that is, absolute humidity) does not change. The fan coil unit (50) blows out the air cooled when passing through the heat exchanger for air conditioning (51) to the indoor space (100a, 100b).

  In each subsystem (11a, 11b), a refrigeration cycle is performed in the refrigerant circuit (60) of the inside air processing unit (56). Specifically, in the inside air processing unit (56), the compressor (61) is operated, and the four-way switching valve (62) is set to the first state. The refrigerant discharged from the compressor (61) flows into the secondary flow path (63b) of the heat source side heat exchanger (63), dissipates heat to the heat source water flowing through the primary flow path (63a), and condenses. To do. Thereafter, the refrigerant expands when passing through the expansion valve (64), then flows into the use side heat exchanger (65), absorbs heat from the indoor air sucked into the use side unit (58), and evaporates. It is sucked into the compressor (61) and compressed again.

  The evaporation temperature of the refrigerant in the use side heat exchanger (65) is usually set to a value lower than the dew point of the room air. For this reason, in the use side heat exchanger (65), condensation occurs, and the sensible heat load and the latent heat load are processed. That is, in the use side heat exchanger (65), the temperature of the air decreases, and the amount of moisture contained in the air decreases (that is, the absolute humidity decreases). The use side unit (58) blows out air that has been cooled and dehumidified when passing through the use side heat exchanger (65) to the indoor space (100a, 100b).

  In each subsystem (11a, 11b), the outside air processing unit (70) ventilates the indoor space (100a, 100b). Specifically, in the outside air processing unit (70), the air supply fan (83) and the exhaust fan (84) operate. The outdoor air processing unit (70) sucks outdoor air from the outdoor air suction port (76), and sucks indoor air in the indoor spaces (100a, 100b) from the indoor air suction port (77). The outdoor air and the indoor air sucked into the outdoor air processing unit (70) flow into the total heat exchanger (81).

  In the total heat exchanger (81), heat and moisture are exchanged between outdoor air and room air. During the cooling of the indoor space (100a, 100b), the temperature and absolute humidity of the indoor air are usually lower than the temperature and absolute humidity of the outdoor air. For this reason, in the total heat exchanger (81), heat and moisture contained in the outdoor air move to the indoor air, and the temperature and absolute humidity of the outdoor air decrease. The outdoor air cooled and dehumidified in the total heat exchanger (81) flows out of the casing (71) through the air supply port (74), and flows from the outlet unit (91) to the indoor space (100a, 100b). Blown out. On the other hand, the indoor air to which heat and moisture are given in the total heat exchanger (81) is discharged to the outside through the exhaust port (75).

<Heating operation>
The heating operation is an operation in which each subsystem (11a, 11b) heats the indoor space (100a, 100b). In each subsystem (11a, 11b) during heating operation, the fan coil unit (50) processes the sensible heat load in the room, the inside air processing unit (56) processes the sensible heat load in the room, and the outside air processing unit ( 70) handles indoor sensible and latent heat loads.

  In the heating operation, the heat source device (15) supplies heat source water (medium hot water for heating) of about 30 ° C. to the subsystems (11a, 11b). In the heating operation, the three-way valve (25a, 25b) corresponding to each subsystem (11a, 11b) is set to the first state, and the four-way switching valve (56) of the internal air processing unit (56) of each subsystem (11a, 11b) 62) is set to the second state. In the heating operation, each of the three-way valves (25a, 25b) is in the first state, so that the heat source water circulation path in the heat source water circuit (20) is in the first circulation state as in the cooling operation.

  The heat source water sent from the heat source device (15) to the feed pipe (30) is distributed to each subsystem (11a, 11b) through the branch pipe (32a, 32b) of the feed pipe (30). In each subsystem (11a, 11b), the heat source water supplied through the feed pipe (30) flows into the air conditioner heat exchanger (51) of the fan coil unit (50). As will be described later, in the heat exchanger for air conditioning (51) of the fan coil unit (50), the heat source water dissipates heat to the air, and the temperature drops to about 26 ° C.

  In each subsystem (11a, 11b), the heat source water flowing out from the heat exchanger for air conditioning (51) passes through the three-way valve (25a, 25b), and the heat source side heat exchanger (63) of the inside air treatment unit (56) Flow into. As will be described later, in the refrigerant circuit (60) of the inside air processing unit (56), a refrigeration cycle in which the heat source side heat exchanger (63) functions as an evaporator is performed. For this reason, the heat source water that has flowed into the primary flow path (63a) of the heat source side heat exchanger (63) radiates heat to the refrigerant in the refrigerant circuit (60), and its temperature drops to about 20 ° C. The heat source water flowing out from the heat source side heat exchanger (63) passes through the branch pipes (42a, 42b) and the collecting pipe (41) of the return pipe (40) in order, and then flows into the heat source device (15).

  In each subsystem (11a, 11b), the fan coil unit (50) supplies the air sucked from the indoor space (100a, 100b) to the air conditioner heat exchanger (51). In the heat exchanger for air conditioning (51), the indoor air sucked into the fan coil unit (50) is heated by exchanging heat with the heat source water. In the heat exchanger for air conditioning (51), only the processing of the sensible heat load is performed. The fan coil unit (50) blows the air heated when passing through the heat exchanger for air conditioning (51) to the indoor space (100a, 100b).

  In each subsystem (11a, 11b), a refrigeration cycle is performed in the refrigerant circuit (60) of the inside air processing unit (56). Specifically, in the inside air processing unit (56), the compressor (61) is operated, and the four-way switching valve (62) is set to the second state. The refrigerant discharged from the compressor (61) flows into the use side heat exchanger (65), dissipates heat to the indoor air sucked into the use side unit (58), and condenses. Thereafter, the refrigerant expands when passing through the expansion valve (64), and then flows into the secondary flow path (63b) of the heat source side heat exchanger (63), and flows through the primary flow path (63a). It absorbs heat from the heat source water and evaporates, and is sucked into the compressor (61) and compressed again.

  In the use side heat exchanger (65) of the inside air processing unit (56), the indoor air sucked into the use side unit (58) is heated. That is, in the use side heat exchanger (65), only the processing of the sensible heat load is performed. The use side unit (58) blows the air heated when passing through the use side heat exchanger (65) to the indoor space (100a, 100b).

  In each subsystem (11a, 11b), the outside air processing unit (70) ventilates the indoor space (100a, 100b). Similar to the cooling operation of the air conditioning system (10), in the outside air processing unit (70), outdoor air and room air sucked into the outside air processing unit (70) flow into the total heat exchanger (81).

  In the total heat exchanger (81), heat and moisture are exchanged between outdoor air and room air. During heating of the indoor space (100a, 100b), the temperature and absolute humidity of the indoor air are usually higher than the temperature and absolute humidity of the outdoor air. For this reason, in the total heat exchanger (81), heat and moisture contained in the indoor air move to the outdoor air, and the temperature and absolute humidity of the outdoor air rise. The outdoor air heated and humidified in the total heat exchanger (81) is further humidified when passing through the humidification element (82). Thereafter, the outdoor air flows out of the casing (71) through the air supply port (74), and is blown out from the outlet unit (91) to the indoor space (100a, 100b). On the other hand, the room air deprived of heat and moisture in the total heat exchanger (81) is discharged to the outside through the exhaust port (75).

<Cooling and heating mixed operation>
The cooling / heating mixed operation is an operation in which one of the two subsystems (11a, 11b) cools the indoor space and the other heats the indoor space. In the air conditioning system (10), the heat source water supplied from the heat source device (15) to each subsystem (11a, 11b) is mixed with cooling and heating in both cases of medium temperature water for cooling and medium temperature water for heating. Can run. Here, the cooling / heating mixed obtaining operation will be described by taking as an example a case where the first subsystem (11a) performs the cooling operation and the second subsystem (11b) performs the heating operation.

  First, the case where the warm water for cooling is supplied from the heat source device (15) to each subsystem (11a, 11b) will be described.

  In this case, the first subsystem (11a) performs the same operation as in the above-described cooling operation, and cools the first indoor space (100a). That is, in the first subsystem (11a), the air cooled by the fan coil unit (50) is supplied to the first indoor space (100a), and the use side unit (58) of the inside air processing unit (56) is cooled and The dehumidified air is supplied to the first indoor space (100a). The operation of the outside air processing unit (70) is the same as that in the cooling operation described above.

  On the other hand, in the second subsystem (11b), the fan coil unit (50) is stopped, and the inside air processing unit (56) and the outside air processing unit (70) are operated. Specifically, in the second subsystem (11b), the second three-way valve (25b) is set to the second state, and heat source water is supplied only to the heat source side heat exchanger (63) of the inside air processing unit (56). Is done. That is, in the heat source water circuit (20), the circulation path of the heat source water is in the second circulation state, and the heat transfer water flowing through the branch pipe (42a) of the feed pipe (30) passes through the use side bypass pipe (24b). It is supplied to the heat source side heat exchanger (63).

  In the inside air processing unit (56), the compressor (61) is operated, and the four-way switching valve (62) is set to the second state. In the inside air processing unit (56), as in the heating operation described above, the refrigeration cycle in which the use side heat exchanger (65) functions as a condenser and the heat source side heat exchanger (63) functions as an evaporator. Is done. In the second subsystem (11b), the air heated in the use side unit (58) of the inside air processing unit (56) is supplied to the second indoor space (100b). The operation of the outside air processing unit (70) is the same as that in the heating operation described above.

  Next, the case where the warm water for heating is supplied from the heat source device (15) to each subsystem (11a, 11b) will be described.

  In this case, in the first subsystem (11a), the fan coil unit (50) is stopped, and the inside air processing unit (56) and the outside air processing unit (70) are operated. Specifically, in the first subsystem (11a), the first three-way valve (25a) is set to the second state, and heat source water is supplied only to the heat source side heat exchanger (63) of the inside air processing unit (56). Is done. That is, in the heat source water circuit (20), the circulation path of the heat source water is in the second circulation state, and the heat transfer water flowing through the branch pipe (32a) of the feed pipe (30) passes through the use side bypass pipe (24a). It is supplied to the heat source side heat exchanger (63).

  In the inside air processing unit (56), the compressor (61) is operated, and the four-way switching valve (62) is set to the first state. In the inside air processing unit (56), as in the cooling operation described above, the refrigeration cycle in which the heat source side heat exchanger (63) functions as a condenser and the use side heat exchanger (65) functions as an evaporator. Is done. In the first subsystem (11a), the air cooled and dehumidified in the use side unit (58) of the inside air processing unit (56) is supplied to the first indoor space (100a). The operation of the outside air processing unit (70) is the same as that in the cooling operation described above.

  On the other hand, the second subsystem (11b) performs the same operation as in the heating operation described above, and heats the second indoor space (100b). That is, in the second subsystem (11b), the air heated by the fan coil unit (50) is supplied to the second indoor space (100b), and the air heated by the use side unit (58) of the inside air processing unit (56). Is supplied to the second indoor space (100b). The operation of the outside air processing unit (70) is the same as that in the heating operation described above.

-Control action-
Control operations performed by the air conditioning controller (17) and the heat source controller (16) will be described.

  As described above, the heat source side controller (16) operates the heat source water pumps (21) of the number determined so that the circulation flow rate of the heat source water in the heat source water circuit (20) becomes the reference flow rate. Specifically, the heat source side controller (16) uses the calendar function provided in the heat source side controller (16) when the air conditioning system (10) is activated, and the date (for example, 6 Month 15).

  As described above, the reference flow rate used for each day of the year is recorded in advance in the memory of the heat source side controller (16). The heat source side controller (16) reads out the value of the reference flow rate corresponding to the identified date (June 15 in the above example) from the memory. And the heat source side controller (16) is a heat source water pump required to make the “total flow rate of the heat source water supplied to each subsystem (11a, 11b)” a “reference flow rate read from the memory”. The number of operating units (21) is determined, and the determined number of heat source water pumps (21) are operated.

  As described above, the reference flow rate is a circulating flow rate of heat source water such that at least a part of the housing load (that is, a part of the indoor air conditioning load) is processed by the fan coil unit (50). For this reason, in the fan coil unit (50) in operation, part of the sensible heat load in the room is processed by cooling or heating the air supplied to the room in the heat exchanger for air conditioning (51).

  On the other hand, the air conditioning side controller (17) controls the air conditioning capability of the inside air processing unit (56) so that the air state of the indoor space (100a, 100b) becomes a predetermined target state. As described above, the air conditioning side controller (17) is configured so that the operating capacity of the compressor (61) and the physical quantity indicating the state of the air in the indoor space (100a, 100b) become the target values. Adjust the opening of the expansion valve (64).

  For example, in the cooling operation, the air conditioning controller (17) sets the target value of the refrigerant evaporation temperature in the use side heat exchanger (65). When the actual refrigerant evaporation temperature exceeds the target value, the air conditioning controller (17) increases the rotational speed of the compressor (61), and the actual refrigerant evaporation temperature falls below the target value. If it is, the air conditioning controller (17) reduces the rotational speed of the compressor (61). In the heating operation, the air conditioning side controller (17) sets the target value of the refrigerant condensing temperature in the use side heat exchanger (65). When the actual refrigerant condensing temperature is lower than the target value, the air conditioning controller (17) increases the rotational speed of the compressor (61), and the actual refrigerant condensing temperature exceeds the target value. If it is, the air conditioning controller (17) reduces the rotational speed of the compressor (61).

  The fan coil unit (50) processes a part of the sensible heat load in the room. The outside air processing unit (70) processes a part of the sensible heat load in the room and a part of the latent heat load. Then, the air-conditioning controller (17) performs the above-described control operation, so that the portion of the indoor air-conditioning load that cannot be processed by the fan coil unit (50) and the outside air processing unit (70) is the inside air processing unit. Processed by (56).

-Effect of Embodiment 1-
In the present embodiment, the heat source controller (16) sets the circulation flow rate of the heat source water in the heat source water circuit (20) to a predetermined reference flow rate. That is, the heat source side controller (16) performs an operation for maintaining the circulation flow rate of the heat source water at the reference flow rate (that is, a relatively simple control operation). For this reason, the configuration of the heat source side controller (16) is very simple. In a state where the circulation flow rate of the heat source water in the heat source water circuit (20) is set to the reference flow rate, a part of the sensible heat load in the room is processed by the fan coil unit (50). On the other hand, the air-conditioning controller (17) adjusts the air-conditioning capacity of the room air processing unit (56), so the portion of the indoor air-conditioning load that could not be processed by the fan coil unit (50) is the room air processing unit (56). And the outside air processing unit (70).

  Thus, in the air conditioning system (10) of the present embodiment, the fan coil unit (50), the inside air processing unit (56), and the outside air processing unit (70) are used while using the heat source side controller (16) with a simple configuration. ) And the indoor air conditioning load can be processed. Therefore, according to the present embodiment, the configuration for controlling the air conditioning system (10) can be simplified without impairing the function of the air conditioning system (10) for reliably processing the air conditioning load in the room. For this reason, according to this embodiment, it becomes possible to reduce the manufacturing cost of an air conditioning system (10).

  In the present embodiment, in the heat source water circuit (20), the heat source side heat exchanger (63) of the inside air treatment unit (56) is disposed downstream of the air conditioning heat exchanger (51) of the fan coil unit (50). Be placed. That is, the heat source water flowing through the heat source water circuit (20) exchanges heat with air in the air conditioner heat exchanger (51), and then exchanges heat with the refrigerant in the refrigerant circuit (60) in the heat source side heat exchanger (63). To do. For this reason, the heat source water sent from the heat source device (15) as compared with the case where the heat source water is supplied individually from the heat source device (15) to the heat exchanger for air conditioning (51) and the heat source side heat exchanger (63). And the temperature difference with the heat source water returning to the heat source device (15) can be expanded. As a result, while maintaining the amount of heat transferred by the heat source water, the circulation flow rate of the heat source water in the heat source water circuit (20) can be reduced, and the power consumption of the heat source water pump (21) can be reduced.

  Moreover, in this embodiment, when the switching mechanism (25a, 25b) switches the flow path of the heat source water, both the fan coil unit (50) that is the first air conditioner and the second air conditioner (55) It is possible to switch between an operating state in which indoor air conditioning is performed and an operating state in which only the second air conditioner (55) performs indoor air conditioning. Therefore, according to the present embodiment, the operating state of the air conditioning system (10) can be selected according to the indoor air conditioning load, and the indoor air conditioning load is processed without excess or deficiency by the air conditioning system (10). It becomes possible.

-Modification of Embodiment 1-
In the air conditioning system (10) of the present embodiment, the switching mechanism (25a, 25b) may be configured by a pair of switching electromagnetic valves (26a, 27a, 26b, 27b) instead of the three-way valves (25a, 25b). Good.

  As shown in FIG. 3, in each subsystem (11a, 11b), one end of the use side bypass pipe (24a, 24b) is connected to the branch pipe (32a, 32b) of the feed pipe (30) and the other end is It connects between the heat exchanger for air conditioning (51) and the heat source side heat exchanger (63) in the branch pipe (42a, 42b) of the return pipe (40). In each branch pipe (32a, 32b) of the feed pipe (30), the first switching solenoid valve (26a, 26b) is disposed downstream of the connection location of the use side bypass pipe (24a, 24b). In addition, the second switching solenoid valve (27a, 27b) is disposed in the use-side bypass pipe (24a, 24b) connected to each branch pipe (32a, 32b).

  When the first switching solenoid valve (26a, 26b) is opened and the second switching solenoid valve (27a, 27b) is closed, the heat source water circulation path in the heat source water circuit (20) is changed to the first circulation state. Become. That is, in the heat source water circuit (20), the heat source water supplied to each subsystem (11a, 11b) through the feed pipe (30) is exchanged with the air conditioner heat exchanger (51) of the fan coil unit (50). It passes through the heat source side heat exchanger (63) of the inside air processing unit (56) in order.

  When the first switching solenoid valve (26a, 26b) is closed and the second switching solenoid valve (27a, 27b) is opened, the flow path of the heat source water in the heat source water circuit (20) is changed to the second flow state. Become. That is, in the heat source water circuit (20), the heat source water supplied to each subsystem (11a, 11b) through the feed pipe (30) passes through the use side bypass pipe (24a, 24b) to the inside air treatment unit ( 56) to the heat source side heat exchanger (63).

<< Embodiment 2 >>
Embodiment 2 will be described. The present embodiment is obtained by changing the configuration of the heat source water circuit (20) in the air conditioning system (10) of the first embodiment.

  As shown in FIG. 4, in the heat source water circuit (20) of the air conditioning system (10) of this embodiment, the air conditioner heat exchanger (51) of the fan coil unit (50) of each subsystem (11a, 11b). And the heat source side heat exchanger (63) of the inside air processing unit (56) are arranged in parallel with each other.

  Specifically, in this embodiment, each branch pipe (32a, 32b) of the feed pipe (30) includes one main pipe (33a, 33b) and two sub pipes (34a, 35a, 34b, 35b) Is provided. In each branch pipe (32a, 32b), the main pipe (33a, 33b) has one end connected to the end of the collecting pipe (31) and the other end connected to one end of each sub pipe (34a, 35a, 34b, 35b). Connected. The other end of the first sub pipe (34a, 34b) is connected to the inflow end of the air conditioning heat exchanger (51) of the fan coil unit (50). The first sub piping (34a, 34b) is provided with a first control valve (36a, 36b) having a variable opening. The other end of the second sub pipe (35a, 35b) is connected to the inflow end of the primary flow path (63a) of the heat source side heat exchanger (63) of the inside air processing unit (56). The second sub piping (35a, 35b) is provided with a second control valve (37a, 37b) having a variable opening.

  In this embodiment, each main pipe (43a, 43b) and two sub pipes (44a, 45a, 44b, 45b) are provided in each branch pipe (42a, 42b) of the return pipe (40). It is done. In each branch pipe (42a, 42b), the main pipe (43a, 43b) has one end connected to the end of the collecting pipe (41) and the other end connected to one end of each sub pipe (44a, 45a, 44b, 45b). Connected. The other end of the first sub pipe (44a, 44b) is connected to the outflow end of the air conditioner heat exchanger (51) of the fan coil unit (50). The other end of the second sub pipe (45a, 45b) is connected to the outflow end of the primary flow path (63a) of the heat source side heat exchanger (63) of the inside air processing unit (56).

  In the heat source water circuit (20) of the air conditioning system (10) of the present embodiment, a part of the heat source water supplied from the heat source device (15) to each subsystem (11a, 11b) is a fan coil unit (50 ) Is supplied to the air conditioner heat exchanger (51), and the remainder is supplied to the heat source side heat exchanger (63) of the inside air processing unit (56). The distribution ratio of the heat source water to the heat exchanger for air conditioning (51) and the heat source side heat exchanger (63) is performed by adjusting the opening degree of the two control valves (36a, 37a, 36b, 37b). In addition, when only the first control valve (36a, 36b) out of the first control valve (36a, 36b) and the second control valve (37a, 37b) is fully closed, each subsystem ( All of the heat source water supplied to 11a, 11b) is supplied to the heat source side heat exchanger (63) of the inside air processing unit (56). And the air conditioning system (10) of this embodiment selectively performs a cooling operation, a heating operation, and a cooling / heating mixed operation similarly to the first embodiment.

<< Other Embodiments >>
In the air conditioning system (10) of each of the above embodiments, a humidity control device that performs dehumidification and humidification of air using an adsorbent may be used as the outside air processing unit (70).

  In the sub-system (11a, 11b) that performs the cooling operation, the outdoor air processing unit (70) of the present modified example supplies the outdoor air dehumidified using the adsorbent to the indoor space (100a, 100b) and the indoor space ( The indoor air sucked from 100a, 100b) is used to regenerate the adsorbent and then discharged to the outdoors. Further, in the subsystem (11a, 11b) that performs the heating operation, the outdoor air processing unit (70) of the present modified example supplies the outdoor air humidified with the adsorbent to the indoor space (100a, 100b), and The indoor air sucked from the space (100a, 100b) is dehumidified with an adsorbent and then discharged to the outside.

  As described above, the present invention is useful for an air conditioner system that includes an air conditioner that adjusts the temperature of air using the heat source fluid itself and an air conditioner that adjusts the temperature of air using the refrigerant in the refrigerant circuit.

10 Air conditioning system
15 Heat source equipment
16 Heat source side controller
17 Air-conditioning side controller
20 Heat source water circuit (heat source fluid circuit)
24a, 24b Use side bypass piping (bypass piping)
25a, 25b Three-way valve (switching mechanism)
26a, 26b 1st switching solenoid valve (switching mechanism)
27a, 26b Second switching solenoid valve (switching mechanism)
50 Fan coil unit (first air conditioner)
51 Heat exchanger for air conditioning
55 2nd air conditioner
56 Inside air treatment unit
60 Refrigerant circuit
63 Heat source side heat exchanger
70 Outside air treatment unit

Claims (4)

A heat source fluid circuit (20) through which the heat source fluid circulates;
A heat source device (15) for cooling or heating the heat source fluid of the heat source fluid circuit (20) so that the temperature of the heat source fluid becomes a predetermined target temperature;
A first air conditioner (50) for supplying air cooled or heated by the heat source fluid of the heat source fluid circuit (20) into the room;
A second air conditioner having a refrigerant circuit (60) for performing a refrigeration cycle by exchanging heat with the heat source fluid of the heat source fluid circuit (20) and supplying air cooled or heated by the refrigerant to the room An air conditioning system comprising a machine (55),
The heat source side that sets the circulation flow rate of the heat source fluid in the heat source fluid circuit (20) to a predetermined reference flow rate so that the first air conditioner (50) processes a part of the sensible heat load in the room. Controller (16),
An air conditioning system comprising: an air conditioning side controller (17) for adjusting the air conditioning capacity of the second air conditioner (55) so that the indoor air condition becomes a predetermined target condition. . In claim 1,
The first air conditioner (50) is provided with an air conditioning heat exchanger (51) for exchanging heat between the heat source fluid of the heat source fluid circuit (20) and air,
The refrigerant circuit (60) of the second air conditioner (55) is provided with a heat source side heat exchanger (63) that exchanges heat between the refrigerant and the heat source fluid of the heat source fluid circuit (20).
In the heat source fluid circuit (20), the heat source side heat exchanger (63) of the second air conditioner (55) is disposed downstream of the air conditioning heat exchanger (51) of the first air conditioner (50). ) Is arranged. In claim 2,
The heat source fluid circuit (20)
Bypass piping (24a, 24b) bypassing the heat exchanger for air conditioning (51),
A first flow state in which the heat source fluid flows into the heat source side heat exchanger (63) after passing through the air conditioning heat exchanger (51); and the heat source fluid passes through the bypass pipes (24a, 24b) An air conditioning system comprising: a switching mechanism (25a, 25b) for switching between the second flow state flowing into the heat source side heat exchanger (63). In any one of Claims 1 thru | or 3,
The first air conditioner (50) is configured to exchange indoor air sucked from the room with the heat source fluid and supply the indoor air to the room,
The second air conditioner (55)
An indoor air processing unit (56) having the refrigerant circuit (60) and configured to supply the indoor air sucked from the room to the room after exchanging heat with the refrigerant;
An air conditioning system comprising: an outdoor air processing unit (70) configured to supply outdoor air sucked from outside after adjusting the temperature and humidity of the outdoor air to the room.

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