JP2009281642A - Heat source device of air conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat source device performing heat exchange between a refrigerant and a heat medium on the utilization side through a heat medium excluding the refrigerant. <P>SOLUTION: This air-conditioning system 10 comprising an indoor-side circuit 80 in which use side heat medium water is circulated, is provided with an outdoor unit 15. The outdoor unit 15 comprises a heat pump unit 20 comprising a refrigerant circuit 21, and a heat transporting circuit 30. In the heat transporting circuit 30, heat source side heat medium water is circulated. Hot heat produced by a refrigerating cycle in the refrigerant circuit 21 is applied to the heat medium on the utilization side through heat source side heat medium water, and utilized in heating a room by an indoor heat exchanger 75. In the heat transporting circuit 30, a normal operation utilizing only hot heat of the heat pump unit 20 in heating, a heat storage operation utilizing only a part of hot heat of the heat pump unit 20 for heating, and storing the remaining heat in a heat storage tank 37, and an utilizing operation for utilizing hot heat of the heat pump unit 20 and the heat storage tank 37 in heating, are selectively performed. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a heat source device provided in an air conditioning system including a utilization side circuit in which a utilization side heat medium circulates.

2. Description of the Related Art Conventionally, an air conditioning system is known in which heat transfer is performed by a use side heat medium circulating in a use side circuit. For example, Patent Literature 1 discloses an air conditioning system in which a heat pump that performs a refrigeration cycle is connected as a heat source device to a use side circuit. In this air conditioning system, a heat exchanger provided in the heat source device exchanges heat between the refrigerant and the use side heat medium, and the use side heat medium heated by the refrigerant is supplied to the floor heating panel connected to the use side circuit. The
JP 2000-46417 A

  The conventional air conditioning system employs a configuration in which the refrigerant circuit of the heat source device is connected to the use side circuit, and the refrigerant in the refrigerant circuit exchanges heat with the use side heat medium. Conventionally, there is only a heat source device that directly heats the usage-side heat medium of such a usage-side circuit with the refrigerant of the refrigerant circuit, and in some cases, the usability may be deteriorated.

  This invention is made | formed in view of this point, The objective is to provide the heat source apparatus which performs heat exchange of a refrigerant | coolant and a utilization side heat medium through heat media other than a refrigerant | coolant.

  1st invention is provided in an air-conditioning system provided with the utilization side circuit (80) to which the heat medium for an air conditioning (75) for air-conditioning a room | chamber interior is circulated while the utilization side heat medium circulates inside, The heat source device that performs at least the operation of heating the utilization side heat medium circulating in the utilization side circuit (80) is intended. The heat source side circuit (30) includes the refrigerant circuit (21) that circulates the refrigerant to perform the refrigeration cycle and the heat source side circuit (30) in which the heat source side heat medium circulates. A heat source side heat exchanger (23) for exchanging heat with the refrigerant in the refrigerant circuit (21), and a use side heat exchanger (35) for exchanging heat of the heat source side heat medium with the use side heat medium And the heat medium on the heat source side is circulated between the heat source side heat exchanger (23) and the use side heat exchanger (35).

  In the first invention, the refrigerant circuit (21) and the heat source side circuit (30) are provided in the heat source device (15). In the heat source device (15), an operation of heating the heat source side heat medium of the heat source side circuit (30) by the refrigerant of the refrigerant circuit (21) is performed. During this operation, in the heat source side heat exchanger (23), the high pressure refrigerant exchanges heat with the heat source side heat medium, and the heat source side heat medium heated by the heat source side heat exchanger (23) becomes the use side heat exchanger (35 ). In the use side heat exchanger (35), the heat source side heat medium and the use side heat medium exchange heat, and the use side heat medium is heated. The utilization side heat medium heated by the utilization side heat exchanger (35) is sent to the air conditioning heat exchanger (75) and used for indoor heating. On the other hand, the heat source side heat medium radiated by the use side heat exchanger (35) is sent back to the heat source side heat exchanger (23) and heated.

  In a second aspect based on the first aspect, the heat source side circuit (30) includes a heat storage tank (37) for storing the heat source side heat medium heated by the heat source side heat exchanger (23). Normal operation for sending only the heat source side heat medium heated by the heat source side heat exchanger (23) to the use side heat exchanger (35), and the heat source side heated by the heat source side heat exchanger (23) A heat storage operation for sending a heat medium to both the use side heat exchanger (35) and the heat storage tank (37), a heat source side heat medium heated by the heat source side heat exchanger (23), and the heat storage tank (37 ) Is configured to selectively perform a use operation of sending both of the heat source side heat medium stored in (1) to the use side heat exchanger (35).

  In the second invention, the heat source side circuit (30) is configured to selectively perform the normal operation, the heat storage operation, and the use operation. In normal operation, only the heat obtained by the refrigeration cycle in the refrigerant circuit (21) is applied to the use-side heat medium. Accordingly, the normal operation is suitable to be performed in a state where the amount of heat generated in the refrigerant circuit (21) and the heating load in the heat exchanger for air conditioning (75) are balanced. On the other hand, in the heat storage operation, a part of the heat obtained by the refrigeration cycle in the refrigerant circuit (21) is applied to the use side heat medium, and the remainder is stored in the heat storage tank (37). If the heat storage operation is performed in a state where the amount of heat generated by the refrigerant circuit (21) is too much for the heating load in the air conditioner heat exchanger (75), surplus heat is stored in the heat storage tank (37). In the use operation, all of the heat obtained by the refrigeration cycle in the refrigerant circuit (21) and the heat stored in the heat storage tank (37) are applied to the use-side heat medium. If the use operation is performed in a state where the amount of heat generated in the refrigerant circuit (21) is insufficient with respect to the heating load in the heat exchanger for air conditioning (75), the amount of heat generated in the refrigerant circuit (21) can be increased. In addition, an amount of heat corresponding to the heating load is applied to the use-side heat medium.

  In a third aspect based on the second aspect, the heat source side circuit (30) includes a temperature sensor (16) for measuring the temperature of the heat source side heat medium at the outlet of the use side heat exchanger (35). When the measured value of the temperature sensor (16) is within the reference range, the normal operation is performed. When the measured value of the temperature sensor (16) is lower than the lower limit value of the reference range, the heat storage operation is performed. When the measured value of the temperature sensor (16) exceeds the upper limit value of the reference range, the use operation is performed.

  In the third aspect of the invention, the normal operation, the heat storage operation, and the use operation are switched according to the measurement value obtained by the temperature sensor (16). The temperature of the heat source side heat medium at the outlet of the use side heat exchanger (35) (that is, the measured value of the temperature sensor (16)) changes according to the relationship of the heating load in the heat exchanger for air conditioning (75). It is a physical quantity. That is, as the heating load on the air conditioning heat exchanger (75) increases, the measured value of the temperature sensor (16) decreases, and as the heating load on the air conditioning heat exchanger (75) decreases, the temperature sensor (16) decreases. The measured value becomes high. Therefore, in the present invention, the normal operation, the heat storage operation, and the use operation are switched based on the measurement value of the temperature sensor (16) that changes in accordance with the heating load in the heat exchanger for air conditioning (75).

  In a fourth aspect based on the second aspect, the heat source side circuit (30) sets the flow rate of the heat source side heat medium in the use side heat exchanger (35) to the heat storage operation, the normal operation, and the use operation. It is comprised so that it may increase in order of.

  In the heat source side circuit (30) of the fourth invention, among the heat storage operation, the normal operation, and the use operation, the operation having a larger heating load in the air conditioner heat exchanger (75) suitable for performing the operation is used. The flow rate of the heat source side heat medium in the heat exchanger (35) increases. For this reason, the heat corresponding to the heating load in the heat exchanger for air conditioning (75) is reliably given to the utilization side heat medium of the utilization side circuit (80).

  In the present invention, the heat source device (15) of the air conditioning system (10) is provided with the refrigerant circuit (21) and the heat source side circuit (30). Then, the heat obtained by the refrigeration cycle in the refrigerant circuit (21) is conveyed by the heat source side heat medium circulating in the heat source side circuit (30), and the use side heat medium in the use side circuit (80) is the heat source side heat medium. Heated by. Therefore, according to the present invention, it is possible to provide an easy-to-use heat source device (15) even when it is difficult to apply a configuration in which the use side heat medium directly exchanges heat with the refrigerant.

  Incidentally, the amount of heat obtained by the refrigeration cycle in the refrigerant circuit (21) is determined by the amount of refrigerant circulating in the refrigerant circuit (21). On the other hand, when the refrigerant circulation amount in the refrigerant circuit (21) changes, the coefficient of performance (COP) of the refrigeration cycle also changes accordingly. The reason is that the performance of the heat exchanger changes when the flow rate of the refrigerant passing through the heat exchanger changes, or the efficiency of the compressor changes when the rotation speed of the compressor changes.

  On the other hand, when the heating capacity is adjusted only by changing the amount of heat obtained by the refrigeration cycle, the fluctuation range of the refrigerant circulation amount in the refrigerant circuit (21) becomes large. As a result, the refrigerant circulation amount in the refrigerant circuit (21) has to be set to a value at which a high coefficient of performance cannot be obtained, and the operation efficiency of the heat source device (15) may be reduced. .

  In contrast, in the second invention, the heat source side circuit (30) is configured to selectively perform the normal operation, the heat storage operation, and the use operation. When the amount of heat obtained in the refrigeration cycle is balanced with the heating load, normal operation is performed.When the amount of heat obtained in the refrigeration cycle is too much for the heating load, heat storage operation is performed. If it is too small for the heating load, the heating capacity obtained by the heat exchanger for air conditioning (75) can be increased without changing the amount of heat obtained by the refrigerant circuit (21) by using each operation. It becomes possible to adjust according to. Therefore, according to the present invention, the fluctuation range of the refrigerant circulation amount in the refrigerant circuit (21) can be suppressed small. As a result, the time during which the refrigerant circulation amount in the refrigerant circuit (21) can be set to a value that can provide a high coefficient of performance can be lengthened, and the operating efficiency of the heat source device (15) can be improved.

  In the third invention, the temperature of the heat source side heat medium at the outlet of the use side heat exchanger (35) is used as a physical quantity that changes according to the relationship of the heating load in the heat exchanger for air conditioning (75). Switching between the normal operation, the heat storage operation, and the use operation is performed based on the actually measured value. Therefore, according to the present invention, switching between the normal operation, the heat storage operation, and the use operation can be appropriately performed according to the heating load in the heat exchanger for air conditioning (75).

  In the fourth aspect of the invention, the flow rate of the heat source side heat medium in the use side heat exchanger (35) is set to an appropriate value in each of the normal operation, the heat storage operation, and the use operation. Therefore, according to this invention, the heat corresponding to the heating load in the heat exchanger for air conditioning (75) can be reliably given to the utilization side heat medium of the utilization side circuit (80).

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

Embodiment 1 of the Invention
A first embodiment of the present invention will be described. The present embodiment is an air conditioning system (10) including an outdoor unit (15) that is a heat source device and an indoor circuit (80) that is a use side circuit. The air conditioning system (10) is configured to heat the room using the heat generated by the outdoor unit (15).

  The air conditioning system (10) of the present embodiment is suitable for installation in a general household in a cold region, for example. In the air conditioning system (10), the indoor circuit (80) may be an existing one. That is, for example, when a heating system in which a boiler is connected to the indoor circuit (80) as a heat source is installed in a house or the like, the outdoor unit (15) is replaced with the indoor circuit (80) instead of the boiler that is the heat source. You may connect.

  As shown in FIG. 1, the outdoor unit (15) is provided with a heat pump unit (20) and a heat transfer circuit (30) which is a heat source side circuit.

  The heat pump unit (20) accommodates a refrigerant circuit (21) filled with a refrigerant. The refrigerant circuit (21) is filled with so-called chlorofluorocarbon refrigerant. However, carbon dioxide may be used in place of the chlorofluorocarbon refrigerant as the refrigerant in the refrigerant circuit (21). A compressor (22), a heat source side heat exchanger (23), an expansion mechanism (24), and an outdoor heat exchanger (25) are sequentially connected to the refrigerant circuit (21).

  The compressor (22) is a compressor having a fixed operating capacity. That is, the electric motor provided in the compressor (22) is always operated at a constant rotational speed. The compressor (22) continuously operates without stopping during the operation of the air conditioning system (10). That is, the compressor (22) performs continuous operation without stopping while water is circulating in the heat transfer circuit (30).

  The heat source side heat exchanger (23) is a plate heat exchanger and includes a plurality of primary side passages (23a) and a plurality of secondary side passages (23b). The heat source side heat exchanger (23) exchanges heat between the fluid flowing through the primary side passage (23a) and the fluid flowing through the secondary side passage (23b). A primary passage (23a) of the heat source side heat exchanger (23) is connected to the refrigerant circuit (21). The expansion mechanism (24) is an electronic expansion valve with a variable opening. The outdoor heat exchanger (25) is a fin-and-tube heat exchanger that exchanges heat between the refrigerant and air. An outdoor fan (26) for sending outdoor air to the outdoor heat exchanger (25) is provided in the vicinity of the outdoor heat exchanger (25).

  The heat transfer circuit (30) is provided with a heat source side heat exchanger (23), a use side heat exchanger (35), and a heat storage tank (37). The heat transfer circuit (30) is filled with heat source side heat transfer water that is a heat source side heat transfer medium.

  The use side heat exchanger (35) is a plate heat exchanger and includes a plurality of primary side passages (35a) and a plurality of secondary side passages (35b). The use side heat exchanger (35) exchanges heat between the fluid flowing through the primary side passage (35a) and the fluid flowing through the secondary side passage (35b). A primary side passage (35a) of the use side heat exchanger (35) and a secondary side passage (23b) of the heat source side heat exchanger (23) are connected to the heat transfer circuit (30). Moreover, the secondary side channel | path (35b) of the utilization side heat exchanger (35) is connected to the indoor side circuit (80).

  The heat transfer circuit (30) is provided with a supply passage (31a) and a return passage (31b). One end of the supply passage (31a) is connected to the outlet end of the secondary passage (23b) of the heat source side heat exchanger (23), and the other end thereof is the primary passage (35a) of the use side heat exchanger (35). ) Is connected to the inlet end. The supply passage (31a) is provided with a first open / close valve (41) that can be freely opened and closed. On the other hand, one end of the return passage (31b) is connected to the outlet end of the primary passage (35a) of the use side heat exchanger (35), and the other end is the secondary passage of the heat source side heat exchanger (23). (23b) connected to the inlet end. The return passage (31b) is provided with a pump (36) having a variable discharge amount. In addition, an outlet temperature sensor (16) for measuring the temperature of the heat-source-side heat transfer water flowing out from the use-side heat exchanger (35) is provided in an upstream portion of the pump (36) in the return passage (31b). Is provided.

  The heat storage tank (37) is a sealed container formed in a vertically long cylindrical shape. The internal space of the heat storage tank (37) is filled with the heat-source-side heat transfer water, and the water temperature is higher above the internal space. An escape passage (57) for releasing the pressure of the heat storage tank (37) is connected to the top of the heat storage tank (37). A relief valve (56) is provided in the relief passage (57).

  Near the upper end of the heat storage tank (37), one end of the hot water passage (61) for allowing the heat source side heat transfer water to flow into the heat storage tank (37) and the heat source side heat transfer water flow out from the heat storage tank (37). One end of the hot water outlet passage (64) is connected. The other end of the hot water passage (61) is connected between the heat source side heat exchanger (23) and the first on-off valve (41) in the supply passage (31a). The hot water passage (61) is provided with a second on-off valve (42) that can be freely opened and closed. On the other hand, the other end of the hot water passage (64) is connected between the first on-off valve (41) and the use side heat exchanger (35) in the supply passage (31a). The hot water passage (64) is provided with a fifth open / close valve (45) that can be freely opened and closed.

  In the return passage (31b), one end of the first communication passage (62a) is connected between the use side heat exchanger (35) and the pump (36), and the pump (36) and the heat source side heat exchanger (23) are connected. One end of the second communication passage (62b) is connected between them. The other ends of the first communication passage (62a) and the second communication passage (62b) are connected to a merge passage (63) connected to the bottom of the heat storage tank (37). The first communication passage (62a) is a passage for communicating the lower part of the heat storage tank (37) to the suction side of the pump (36). A fourth open / close valve (44) that can be freely opened and closed is provided in the first communication passage (62a). On the other hand, the second communication passage (62b) is a passage for communicating the lower part of the heat storage tank (37) to the discharge side of the pump (36). A third open / close valve (43) that can be freely opened and closed is provided in the second communication passage (62b).

  A water supply pipe (65) is connected to the junction passage (63) connected to the bottom of the heat storage tank (37). The water supply pipe (65) is a pipe for supplying water to the heat transfer circuit (30) including the heat storage tank (37), and is connected to a water supply or the like. The water supply pipe (65) is provided with a check valve (66). The check valve (66) is configured to permit the flow of water in the direction of flowing into the merge passage (63) and to block the flow of water in the direction of flowing out of the merge passage (63).

  In the heat transfer circuit (30) of the present embodiment, only the heat source side heat transfer water heated by the heat source side heat exchanger (23) is controlled by controlling the first to fifth on-off valves (41 to 45). Normal operation to supply each use side heat exchanger (35) and heat source side heat transfer water heated by the heat source side heat exchanger (23) to each use side heat exchanger (35) and heat storage tank (37) The heat storage operation supplied to both the heat source side heat transfer water heated in the heat source side heat exchanger (23) and the heat source side heat transfer water in the heat storage tank (37) are used for each use side heat exchanger (35 Any one of the three types of use operations to be supplied to () is performed. The controller (50) is configured to switch between normal operation, heat storage operation, and use operation.

  The indoor circuit (80) is a closed circuit filled with use side heat transfer water that is a use side heat medium. The indoor circuit (80) is provided with a plurality of indoor heat exchangers (75) that are heat exchangers for air conditioning. An indoor heat exchanger (75) is a radiator for floor heating installed in the back side of the floor material which is a division member which divides a room, and a radiator installed in indoor space.

  In the indoor circuit (80), the plurality of indoor heat exchangers (75) are connected in parallel to each other. Specifically, in the indoor side circuit (80), a supply side header (73) is connected to the outlet end of the secondary side passage (35b) of the use side heat exchanger (35), and the supply side header (73) One end of each indoor heat exchanger (75) is connected. In the indoor circuit (80), a return header (74) is connected to the inlet end of the secondary passage (35b) of the use side heat exchanger (35), and each return chamber (74) is connected to each indoor header (74). The other end of the heat exchanger (75) is connected.

  The indoor side circuit (80) is provided with an indoor pump (76) between the return side header (74) and the use side heat exchanger (35). The discharge flow rate of the indoor pump (76) is set to a constant value. Further, a closed container-like expansion tank (78) is connected to the suction side of the indoor pump (76) to absorb the volume change of the use-side heat transfer water.

-Driving action-
Operation | movement of the air conditioning system (10) of this embodiment is demonstrated. In this air conditioning system (10), while the power is on, the compressor (22) of the refrigerant circuit (21), the pump (36) of the heat transfer circuit (30), and the indoor circuit ( 80) Indoor pump (76) performs continuous operation.

  In the air conditioning system (10), the heat transfer circuit (30) of the outdoor unit (15) selectively performs a normal operation, a heat storage operation, and a use operation. On the other hand, the indoor side circuit (80) and the heat pump unit (20) of the outdoor unit (15) perform the same operation regardless of the operation of the heat transfer circuit (30). Here, the operation of the indoor circuit (80) and the heat pump unit (20) will be described first, and then the normal operation, the heat storage operation, and the use operation of the heat transfer circuit (30) will be described in order.

<Operation of indoor circuit>
The operation of the indoor circuit (80) will be described. During the operation of the indoor pump (76), the utilization side heat transfer water circulates between the utilization side heat exchanger (35) and the indoor heat exchanger (75) in the indoor circuit (80).

  Specifically, the use side heat transfer water flowing into the secondary side passage (35b) of the use side heat exchanger (35) is heated by the heat source side heat transfer water flowing through the primary side passage (35a). The utilization side heat transfer water heated by the utilization side heat exchanger (35) flows into the supply side header (73) and is distributed to each indoor heat exchanger (75). In the indoor heat exchanger (75), the use-side heat transfer water dissipates heat, and the temperature of the use-side heat transfer water decreases. The usage-side heat transfer water radiated by each indoor heat exchanger (75) flows into the return header (74), joins it, and is sucked into the indoor pump (76), and then the usage-side heat exchanger ( It flows into the secondary passage (35b) of 35).

<Operation of heat pump unit>
The operation of the heat pump unit (20) will be described. In the refrigerant circuit (21) of the heat pump unit (20), a refrigeration cycle is performed by circulating the refrigerant. In the refrigerant circuit (21), the opening degree of the expansion mechanism (24) is appropriately adjusted.

  Specifically, the refrigerant discharged from the compressor (22) flows into the primary side passage (23a) of the heat source side heat exchanger (23) and dissipates heat to the heat source side heat transfer water in the secondary side passage (23b). And condense. The refrigerant condensed in the heat source side heat exchanger (23) expands when passing through the expansion mechanism (24), and then absorbs heat from the outdoor air sent by the outdoor fan (26) in the outdoor heat exchanger (25). Evaporate. The refrigerant evaporated in the outdoor heat exchanger (25) returns to the compressor (22), is compressed, and is discharged again.

<Normal operation of heat transfer circuit>
As shown in FIG. 2, in the normal operation, the first on-off valve (41) is set to the open state, and the second on-off valve (42), the third on-off valve (43), the fourth on-off valve (44), and the 5 The on-off valve (45) is set to the closed state. During normal operation, in the heat transfer circuit (30), only the heat source side heat transfer water heated by the heat source side heat exchanger (23) is supplied to the use side heat exchanger (35).

  The heat source side heat transfer water flowing into the secondary side passage (23b) of the heat source side heat exchanger (23) is heated by the refrigerant flowing through the primary side passage (23a). The heat source side heat transfer water heated by the heat source side heat exchanger (23) flows into the primary side passage (35a) of the use side heat exchanger (35) through the supply passage (31a). In the primary side passage (35a) of the use side heat exchanger (35), the heat source side heat transfer water dissipates heat to the use side heat transfer water of the secondary side passage (35b), and the temperature of the heat source side heat transfer water decreases. . The heat-source-side heat transfer water radiated by the use-side heat exchanger (35) is sucked into the pump (36) through the return passage (31b), and then the secondary-side passage ( 23b).

  During normal operation, the heat generated by the refrigeration cycle in the heat pump unit (20) is given to the heat source side heat transfer water, and the heat given to the heat source side heat transfer water is further given to the use side heat transfer water. And the warm heat given to utilization side heat transfer water is used for indoor heating.

<Heat storage operation of heat transfer circuit>
As shown in FIG. 3, in the heat storage operation, the first on-off valve (41), the second on-off valve (42), and the fourth on-off valve (44) are set in the open state, and the third on-off valve (43) and the second on-off valve (43) 5 The on-off valve (45) is set to the closed state. The discharge flow rate of the pump (36) is set to the same value as during normal operation. During the heat storage operation, in the heat transfer circuit (30), the heat source side heat transfer water heated by the heat source side heat exchanger (23) is supplied to both the use side heat exchanger (35) and the heat storage tank (37). Is done.

  The heat source side heat transfer water flowing into the secondary side passage (23b) of the heat source side heat exchanger (23) is heated by the refrigerant flowing through the primary side passage (23a). Part of the heat source side heat transfer water heated by the heat source side heat exchanger (23) flows into the primary side passage (35a) through the supply passage (31a), The rest flows into the hot water passage (61). The heat source side heat transfer water flowing into the primary side passage (35a) of the use side heat exchanger (35) returns after radiating heat to the use side heat transfer water of the secondary side passage (35b) as in normal operation. It flows into the passage (31b).

  On the other hand, the heat source side heat transfer water flowing into the hot water passage (61) flows into the upper end portion of the internal space of the heat storage tank (37). From the heat storage tank (37), the low-temperature heat source side heat transfer water present at the bottom of the internal space is pushed out to the junction passage (63). For this reason, in the internal space of the heat storage tank (37), the amount of high-temperature heat source side heat transfer water increases. That is, the amount of heat stored in the heat storage tank (37) increases. The flow rate of the heat source side heat transfer water flowing out from the heat storage tank (37) to the junction passage (63) is equal to the flow rate of the heat source side heat transfer water flowing into the heat storage tank (37) from the hot water supply passage (61). The heat-source-side heat transfer water flowing out from the heat storage tank (37) to the merge passage (63) joins the heat-source-side heat transfer water radiated by the use-side heat exchanger (35), and is sucked into the pump (36). Into the secondary side passage (23b) of the heat source side heat exchanger (23).

  During the heat storage operation, the heat generated by the refrigeration cycle in the heat pump unit (20) is applied to the heat source side heat transfer water. A part of the heat given to the heat source side heat transfer water is given to the use side heat transfer water and used for indoor heating, and the rest is stored in the heat storage tank (37).

<Use operation of heat transfer circuit>
As shown in FIG. 4, in the use operation, the first on-off valve (41), the third on-off valve (43), and the fifth on-off valve (45) are set in the open state, and the second on-off valve (42) and the second on-off valve (42) 4 The on-off valve (44) is set to the closed state. The discharge flow rate of the pump (36) is set to a larger value than during normal operation. During the use operation, in the heat transfer circuit (30), the heat source side heat transfer water heated by the heat source side heat exchanger (23) and the high temperature heat source side heat transfer water stored in the heat storage tank (37) Are supplied to the use side heat exchanger (35).

  The heat source side heat transfer water flowing into the secondary side passage (23b) of the heat source side heat exchanger (23) is heated by the refrigerant flowing through the primary side passage (23a). The heat source side heat transfer water heated by the heat source side heat exchanger (23) flows into the primary side passage (35a) of the use side heat exchanger (35) through the supply passage (31a).

  On the other hand, heat source side heat transfer water is fed into the heat storage tank (37) from the junction passage (63) to the bottom of the internal space. For this reason, from the heat storage tank (37), the high-temperature heat source side heat transfer water present in the upper part of the internal space is pushed out to the hot water passage (64). The heat source side heat transfer water flowing out from the heat storage tank (37) to the hot water passage (64) flows into the primary side passage (35a) of the use side heat exchanger (35).

  In the internal space of the heat storage tank (37), the amount of high-temperature heat source side heat transfer water decreases. That is, the amount of heat stored in the heat storage tank (37) decreases. The flow rate of the heat source side heat transfer water flowing out from the heat storage tank (37) to the hot water passage (64) is equal to the flow rate of the heat source side heat transfer water flowing into the heat storage tank (37) from the merge passage (63).

  The heat source side heat transfer water flowing into the primary side passage (35a) of the use side heat exchanger (35) returns after radiating heat to the use side heat transfer water of the secondary side passage (35b) as in normal operation. It flows into the passage (31b). The heat source side heat transfer water flowing into the return passage (31b) is sucked into the pump (36). Part of the heat source side heat transfer water discharged from the pump (36) flows into the secondary side passage (23b) of the heat source side heat exchanger (23), and the rest passes through the junction passage (63). It flows into the heat storage tank (37). The heat-source-side heat transfer water flowing into the secondary-side passage (23b) of the heat-source-side heat exchanger (23) is heated by the refrigerant in the primary-side passage (23a) as in normal operation.

  During the use operation, both the heat generated by the refrigeration cycle in the heat pump unit (20) and the heat stored in the heat storage tank (37) are given to the use-side heat transfer water. And the warm heat given to utilization side heat transfer water is used for indoor heating.

-Controller operation-
Control operations performed by the controller (50) will be described. The controller (50) receives the measured value (To) of the outlet temperature sensor (16) and the indoor set temperature (Ts). The controller (50) is configured to select one of the normal operation, the heat storage operation, and the use operation based on these input values, and to cause the heat transfer circuit (30) to execute the selected operation. Has been.

  In the controller (50), a first determination value (T1) and a second determination value (T2) for selecting the operation of the heat transfer circuit (30) are set in advance. The first determination value (T1) is a positive value, and the second determination value (T2) is a negative value. Further, the first determination value (T1) and the second determination value (T2) have the same absolute value. Then, the controller (50) determines the difference (To−Ts) between the measured value (To) of the outlet temperature sensor (16) and the indoor set temperature (Ts) as the first determination value (T1) and the second determination value. Compared with (T2), one of the normal operation, the heat storage operation, and the use operation is selected based on the result.

When the following equation 1 is established, the controller (50) indicates that the measured value of the temperature of the heat source side heat transfer water at the outlet of the primary side passage (35a) of the use side heat exchanger (35) is within the reference range (T2 + Ts When it is determined that the value is within the range of T1 + Ts or less, normal operation is selected.
Formula 1: T2 ≦ To−Ts ≦ T1

  When the above equation 1 is satisfied, the difference between the measured value (To) of the outlet temperature sensor (16) and the indoor set temperature (Ts) is not so large, and the heating capacity of the indoor heat exchanger (75) is It can be judged that it is in general balance with the indoor heating load. Therefore, in this case, the controller (50) selects the normal operation. When the controller (50) selects normal operation, the controller opens the first on-off valve (41), opens the second on-off valve (42), the third on-off valve (43), the fourth on-off valve (44), and By setting the fifth on-off valve (45) to the closed state, the heat transfer circuit (30) is caused to perform a normal operation.

When the following equation 2 is established, the controller (50) is, in other words, the measured value of the temperature of the heat source side heat transfer water at the outlet of the primary side passage (35a) of the use side heat exchanger (35) is the upper limit of the reference range. When it is determined that the value (T1 + Ts) is exceeded, the heat storage operation is selected.
Formula 2: T1 <To-Ts

  When the above equation 2 holds, the measured value (To) of the outlet temperature sensor (16) is significantly higher than the indoor set temperature (Ts), and the heating capacity of the indoor heat exchanger (75) is indoors. It can be determined that it is too large for the heating load. Therefore, in this case, the controller (50) selects the heat storage operation. When the controller (50) selects the heat storage operation, the controller opens the first on-off valve (41), the second on-off valve (42), and the fourth on-off valve (44), and opens the third on-off valve (43) and By setting the fifth on-off valve (45) to a closed state, the heat transfer circuit (30) is caused to perform a heat storage operation. The controller (50) sets the discharge flow rate of the pump (36) to the same value as during normal operation.

When the controller (50) determines that the following Equation 3 is satisfied, that is, when the temperature of the water that has passed through each use-side heat exchanger (35) is below the lower limit (T2 + Ts) of the reference range, Select usage behavior.
Formula 3: To-Ts <T2

  When the above equation 3 holds, the measured value (To) of the outlet temperature sensor (16) is significantly lower than the indoor set temperature (Ts), and the heating capacity of the indoor heat exchanger (75) is indoors. It can be judged that it is too small with respect to a heating load. Therefore, in this case, the controller (50) selects the use operation. When the controller (50) selects the use operation, the controller (50) sets the first on-off valve (41), the third on-off valve (43), and the fifth on-off valve (45) to the open state, and the second on-off valve (42) and By setting the fourth on-off valve (44) to the closed state, the heat transfer circuit (30) is caused to perform the use operation. In addition, the controller (50) sets the discharge flow rate of the pump (36) to a larger value than during normal operation.

-Effect of Embodiment 1-
In the present embodiment, a refrigerant circuit (21) and a heat transfer circuit (30) are provided in the outdoor unit (15) of the air conditioning system (10). Then, the heat obtained by the refrigeration cycle in the refrigerant circuit (21) is conveyed by the heat source side heat transfer water circulating through the heat transfer circuit (30), and the use side heat transfer water in the indoor side circuit (80) is transferred to the heat source side. Heated by heat transfer water. Therefore, according to the present embodiment, it is possible to provide an easy-to-use outdoor unit (15) even when it is difficult to apply a configuration in which the use-side heat transfer water directly exchanges heat with the refrigerant.

  Incidentally, the amount of heat obtained by the refrigeration cycle in the refrigerant circuit (21) is determined by the amount of refrigerant circulating in the refrigerant circuit (21). On the other hand, when the refrigerant circulation amount in the refrigerant circuit (21) changes, the coefficient of performance (COP) of the refrigeration cycle also changes accordingly. The reason is that the performance of the heat exchanger changes when the flow rate of the refrigerant passing through the heat exchanger changes, or the efficiency of the compressor changes when the rotation speed of the compressor changes.

  On the other hand, when the heating capacity is adjusted only by changing the amount of heat obtained by the refrigeration cycle, the fluctuation range of the refrigerant circulation amount in the refrigerant circuit (21) becomes large. As a result, the amount of refrigerant circulating in the refrigerant circuit (21) (specifically, the rotational speed of the compressor (22)) has to be set to a value that does not provide a high coefficient of performance, and the time becomes longer. The operating efficiency of the outdoor unit (15) could be reduced.

  On the other hand, in this embodiment, the heat transfer circuit (30) is configured to selectively perform a normal operation, a heat storage operation, and a use operation. When the amount of heat obtained in the refrigeration cycle is balanced with the heating load, normal operation is performed.When the amount of heat obtained in the refrigeration cycle is too much for the heating load, heat storage operation is performed. If there is too little for the heating load, the heating capacity obtained by the indoor heat exchanger (75) can be heated even if the usage amount is not adjusted, if the amount of heat obtained by the refrigerant circuit (21) cannot be actively adjusted. It can be adjusted according to the load.

  That is, according to the present embodiment, the heating capacity obtained by the indoor heat exchanger (75) is set according to the heating load even though the rotational speed of the compressor (22) of the refrigerant circuit (21) is fixed. Can be adjusted. Therefore, according to the present embodiment, the heating capacity in the indoor heat exchanger (75) can be adjusted, and the rotational speed of the compressor (22) can be maintained at a value that provides a high coefficient of performance. The operation efficiency of the unit (15) can be improved.

  In the present embodiment, the heat source side heat medium at the outlet of the primary side passage (35a) of the use side heat exchanger (35) is used as a physical quantity that changes according to the relationship of the heating load in the indoor heat exchanger (75). Using the temperature of water, switching between normal operation, heat storage operation, and utilization operation is performed based on the measured value. Therefore, according to the present embodiment, switching between the normal operation, the heat storage operation, and the use operation can be appropriately performed according to the heating load in the indoor heat exchanger (75).

  In the present embodiment, the flow rate of the heat source side heat transfer water in the primary side passage (35a) of the use side heat exchanger (35) is set to an appropriate value in each of the normal operation, the heat storage operation, and the use operation. The Therefore, according to this embodiment, the heat corresponding to the heating load in the indoor heat exchanger (75) can be reliably imparted to the use-side heat transfer water of the indoor circuit (80).

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described. The present embodiment is obtained by changing the configuration of the heat transfer circuit (30) of the outdoor unit (15) in the air conditioning system (10) of the above embodiment. Here, the difference from the first embodiment will be described for the heat transfer circuit (30) of the present embodiment.

  As shown in FIG. 5, a sub pump (39) is added to the heat transfer circuit (30) of the present embodiment. Accordingly, in the heat transfer circuit (30) of the present embodiment, the pump disposed in the return passage (31b) is the main pump (36). In the heat transfer circuit (30) of the present embodiment, the second communication passage (62b) is connected between the heat source side heat exchanger (35) and the main pump (36) in the return passage (31b). A sub pump (39) is provided in the two communication passages (62b).

  The sub pump (39) is operated only during the use operation, and is stopped during the normal operation and the heat storage operation. The main pump (36) is operated in all of the normal operation, the heat storage operation, and the use operation, as in the first embodiment. In the heat transfer circuit (30) during use operation, a part of the heat source side heat transfer water that has passed through the primary side passage (35a) of the use side heat exchanger (35) is sucked into the sub pump (39), The rest is sucked into the main pump (36). The heat-source-side heat transfer water sucked into the sub pump (39) is sent to the bottom of the heat storage tank (37) through the merge passage (63). Then, the high-temperature heat-source-side heat transfer water present in the upper part of the heat storage tank (37) is pushed out to the hot water passage (64) and sent to the use-side heat exchanger (35). On the other hand, the heat source side heat transfer water sucked into the main pump (36) flows into the secondary side passage (23b) of the heat source side heat exchanger (23) and is heated, and then passes through the supply passage (31a). To the use side heat exchanger (35).

  Note that, unlike the first embodiment, the discharge flow rate of the main pump (36) during the use operation is set to the same value as during the normal operation. That is, the discharge flow rate of the main pump (36) is always constant. For this reason, a pump with a fixed discharge flow rate can be used for the main pump (36).

  In this embodiment, the flow rate of the heat source side heat transfer water sent to the lower part of the heat storage tank (37) during the use operation is determined by the discharge flow rate of the sub pump (39). That is, the flow rate of the hot water supplied from the heat storage tank (37) to the use side heat exchanger (35) during the use operation is determined by the discharge flow rate of the sub pump (39). For this reason, according to this embodiment, the flow rate of the heat source side heat transfer water supplied from the heat storage tank (37) to the use side heat exchanger (35) during the use operation can be easily set to a desired flow rate. it can.

<< Embodiment 3 of the Invention >>
Embodiment 3 of the present invention will be described. In this embodiment, in the air conditioning system (10) of the above embodiment, the heating operation and the cooling operation can be switched.

  As shown in FIG. 6, in the air conditioning system (10) of the present embodiment, the configuration of the refrigerant circuit (21) of the outdoor unit (15) is different from that of the first embodiment. Here, the difference from the first embodiment will be described for the refrigerant circuit (21) of the present embodiment.

  A four-way switching valve (27) is added to the refrigerant circuit (21) of the present embodiment. The four-way switching valve (27) has a first port on the discharge side of the compressor (22), a second port on the suction side of the compressor (22), and a third port on the heat source side heat exchanger ( 23) The fourth port is connected to the primary passage (23a) and the outdoor heat exchanger (25), respectively. The four-way switching valve (27) is configured such that the discharge side of the compressor (22) communicates with the outdoor heat exchanger (25) and the suction side of the compressor (22) communicates with the heat source side heat exchanger (23). The state (shown by the solid line in FIG. 6), the discharge side of the compressor (22) communicates with the heat source side heat exchanger (23), and the suction side of the compressor (22) communicates with the outdoor heat exchanger (25). The state is switched to the second state (the state indicated by the broken line in FIG. 6).

  During the heating operation of the air conditioning system (10), the four-way selector valve (27) is set to the second state (the state indicated by the broken line in FIG. 6), and the heat source side heat exchanger (23) serves as a condenser and is outdoors. A refrigeration cycle in which the heat exchanger (25) serves as an evaporator is performed in the refrigerant circuit (21). Further, during the heating operation, the heat transfer circuit (30) selectively performs a normal operation, a heat storage operation, and a use operation.

  On the other hand, during the cooling operation of the air conditioning system (10), the four-way switching valve (27) is set to the first state (the state indicated by the solid line in FIG. 6), and the outdoor heat exchanger (25) serves as a condenser. A refrigeration cycle in which the heat source side heat exchanger (23) serves as an evaporator is performed in the refrigerant circuit (21). During the cooling operation, the heat transfer circuit (30) performs a normal operation (see FIG. 6). That is, in the heat transfer circuit (30) during the cooling operation, the heat source side heat transfer water cooled by the heat source side heat exchanger (23) is sent to the use side heat exchanger (35), and the use side heat exchanger ( The heat-source-side heat transfer water that has absorbed heat from the use-side heat transfer water in 35) is sent back to the heat-source-side heat exchanger (23) and cooled again. Further, in the indoor side circuit (80) during the cooling operation, the usage side heat transfer water cooled by the usage side heat exchanger (35) is sent to the indoor heat exchanger (75), and the indoor heat exchanger (75) Then, the utilization side heat transfer water that has absorbed heat from indoor air or the like is sent back to the utilization side heat exchanger (35) and cooled again.

<< Other Embodiments >>
-First modification-
In the heat transfer circuit (30) of each of the above embodiments, as shown in FIG. 7, the escape passage (57) and the relief valve (56) may be omitted and an expansion tank (38) may be added. . The expansion tank (38) is formed in a closed container shape. The expansion tank (38) is connected to the suction side of the pump (36) in the heat transfer circuit (30) in order to absorb the volume change of the heat source side heat transfer water.

-Second modification-
In each of the above embodiments, the indoor side circuit (80) is a closed circuit in which the use-side heat transfer water circulating inside does not come into contact with the atmosphere, but the indoor side circuit (80) circulates inside. The utilization side heat transfer water may be an open circuit in contact with the atmosphere. The indoor side circuit (80) configured as an open circuit is connected to an open tank in which the water surface inside is in contact with the atmosphere, instead of the expansion container (78) in a sealed container shape.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for the heat source device provided in the air conditioning system.

It is a piping system diagram showing the composition of the air-conditioning system of Embodiment 1. It is a piping system diagram of the air-conditioning system of Embodiment 1 which shows the flow of the heat source side heat carrier water under normal operation. It is a piping system diagram of the air-conditioning system of Embodiment 1 which shows the flow of the heat source side heat-transfer water during heat storage operation. It is a piping system diagram of the air-conditioning system of Embodiment 1 which shows the flow of the heat source side heat carrier water in use operation. It is a piping system diagram which shows the structure of the air conditioning system of Embodiment 2, and the flow of the heat-source side heat transfer water in use operation. It is a piping system diagram which shows the structure of the air-conditioning system of Embodiment 3, and the flow of the heat-source side heat transfer water in normal operation. It is a piping system diagram which shows the structure of the air conditioning system of the 1st modification of other embodiment.

Explanation of symbols

10 Air conditioning system
15 Outdoor unit (heat source device)
16 Outlet temperature sensor (temperature sensor)
21 Refrigerant circuit
23 Heat source side heat exchanger
30 Heat transfer circuit (heat source side circuit)
35 User-side heat exchanger
37 Thermal storage tank
75 Indoor heat exchanger (heat exchanger for air conditioning)
80 Indoor side circuit (use side circuit)

Claims (4)

The use side heat medium circulates inside and is provided in an air conditioning system including a use side circuit (80) to which an air conditioning heat exchanger (75) for air conditioning the room is connected, and the use side circuit (80) A heat source device that performs at least an operation of heating the use side heat medium circulating through
While comprising a refrigerant circuit (21) that circulates refrigerant to perform a refrigeration cycle, and a heat source side circuit (30) through which the heat source side heat medium circulates,
The heat source side circuit (30) includes a heat source side heat exchanger (23) for exchanging heat of the heat source side heat medium with the refrigerant of the refrigerant circuit (21), and the heat source side heat medium as the use side heat medium. And a use side heat exchanger (35) for heat exchange with the heat source side heat exchanger (23) and the use side heat exchanger (35) so as to circulate the heat source side heat medium. It is comprised in the heat source apparatus of the air conditioning system characterized by the above-mentioned. In claim 1,
The heat source side circuit (30) includes a heat storage tank (37) for storing the heat source side heat medium heated by the heat source side heat exchanger (23), and is heated by the heat source side heat exchanger (23). Normal operation of sending only the heat source side heat medium to the use side heat exchanger (35), and the heat source side heat medium heated by the heat source side heat exchanger (23) to the use side heat exchanger (35). Both the heat storage operation to be sent to both the heat storage tank (37), the heat source side heat medium heated by the heat source side heat exchanger (23) and the heat source side heat medium stored in the heat storage tank (37) are described above. A heat source device for an air conditioning system, wherein the heat source device is configured to selectively perform a use operation to be sent to a use side heat exchanger (35). In claim 2,
The heat source side circuit (30) includes a temperature sensor (16) for measuring the temperature of the heat source side heat medium at the outlet of the use side heat exchanger (35), and the measured value of the temperature sensor (16) is within a reference range. If the measured value of the temperature sensor (16) falls below the lower limit of the reference range, the heat storage operation is performed, and the measured value of the temperature sensor (16) is within the reference range. A heat source device of an air conditioning system configured to perform the above utilization operation when an upper limit value is exceeded. In claim 2,
The heat source side circuit (30) is configured to increase the flow rate of the heat source side heat medium in the use side heat exchanger (35) in the order of the heat storage operation, the normal operation, and the use operation. Heat source device for air conditioning system.

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