JP2019174006A - Air conditioning system - Google Patents

Abstract

To provide an air conditioning system capable of performing defrost operation without performing cooling.SOLUTION: An air conditioning system 1 comprises a heat pump device 2, a hot water supply device 3, and a control portion. The control portion can perform a refrigeration cycle heating operation and a heat medium heating operation. In the refrigeration cycle heating operation, the heat pump device 2 is driven, and the hot water supply device 3 is not driven. In the heat medium heating operation, the heat pump device 2 is not driven and the hot water supply device 3 is driven. The heat pump device 2 has a refrigerant flow channel switching device 29 switching a refrigeration cycle refrigerant flow channel constituting a refrigeration cycle and a bypass refrigerant flow channel not constituting the refrigeration cycle. The heat pump device 2 further comprises a refrigerant heat medium heat exchanger 15 exchanging heat between a heat medium flow channel 32 of the hot water supply device 3 and the bypass refrigerant flow channel.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air conditioning system, and more particularly to an air conditioning system including a heat pump device and a hot water supply device.

  2. Description of the Related Art Conventionally, in a heat pump device, a technique for defrosting by reversing a refrigeration cycle is known in order to eliminate frost formation on a coil (for example, see Patent Document 1).

JP 2001-280769 A

  In the invention described in Patent Document 1, when heating is performed, there is a problem that cooling is performed by reversal of the refrigeration cycle.

  This invention is invented in view of the said conventional problem, Comprising: It is providing the air-conditioning system which can perform the defrost operation | movement which defrosts without performing cooling.

  In order to solve the above problem, an air conditioning system according to a first aspect includes a heat pump device, a hot water supply device, and a control unit. The heat pump device includes a compressor, an outdoor refrigerant heat exchanger, an expansion mechanism, and an indoor refrigerant heat exchanger. The hot water supply apparatus includes a heat medium flow path, an indoor heat medium heat exchanger that is provided in the middle of the heat medium flow path and applies heat to the air flowing through the indoor flow path, and the indoor heat medium heat exchanger. A heat source that heats the heat medium that flows through the heat source. The control unit controls the heat pump device and the hot water supply device. The control unit can execute a refrigeration cycle heating operation that drives the heat pump device and does not drive the hot water supply device, and a heat medium heating operation that does not drive the heat pump device and drives the hot water supply device.

  The heat pump device includes a refrigerant channel switching device that switches between a refrigeration cycle refrigerant channel and a bypass refrigerant channel. In the refrigeration cycle refrigerant flow path, the refrigerant flows through the compressor, the outdoor refrigerant heat exchanger, the expansion mechanism, and the indoor refrigerant heat exchanger to constitute a refrigeration cycle. In the bypass refrigerant flow path, the refrigerant flows through the compressor, the outdoor refrigerant heat exchanger, and the expansion mechanism, but does not flow through the indoor refrigerant heat exchanger. The air conditioning system includes a refrigerant heat medium heat exchanger that exchanges heat between the bypass refrigerant flow path and the heat medium flow path.

  The invention according to claim 2 is the invention according to claim 1, wherein the hot water supply device includes a state in which the heat medium flows through a heating heat medium flow path as the heat medium flow path, and the heat medium A heat medium flow switching device that switches between a bypass heat medium flow path as the heat medium flow path and a state in which both of the heating heat medium flow paths are passed. In the heating heat medium flow path, the heat medium circulates through the heat source section and the indoor heat medium heat exchanger. The bypass refrigerant flow path circulates so that the heat medium flows through the heat source section and the refrigerant heat medium heat exchanger but does not flow through the indoor heat medium heat exchanger. The refrigerant heat medium heat exchanger is arranged to exchange heat between the bypass refrigerant flow path and the bypass heat medium flow path.

  According to a third aspect of the present invention, in the second aspect of the present invention, the control unit performs a predetermined defrost determination. The control unit performs the refrigeration cycle heating operation when it is not determined that the defrost is necessary in the defrost determination. When it is determined that defrost is required in the defrost determination, the control unit causes the refrigerant flow switching device to switch to configure the bypass refrigerant flow path, and causes the refrigerant to flow through the bypass refrigerant flow path. And switching the heating medium flow switching device to configure the heating heat medium flow path and the bypass heat medium flow path so that the heating medium is switched to the heating heat medium flow path and the bypass heat medium flow path. Let it flow.

  In the invention which concerns on Claim 1, heat exchange can be performed between a bypass refrigerant flow path and a heat-medium flow path, performing the heating operation using a heat-medium. At this time, since the refrigerant flowing through the bypass refrigerant channel does not flow through the indoor refrigerant heat exchanger, the indoor refrigerant heat exchanger can be prevented from being cooled and the air-conditioning target space being cooled. In addition, this is achieved with a simple configuration.

  In the invention according to claim 2, while performing the heating operation by passing the heating medium through the heating heating medium flow path, the heating medium is passed through the bypass heating medium flow path so that the heat necessary for defrosting is efficiently obtained. Can be supplied well.

  In the invention according to claim 3, only when it is determined that defrost is required in the defrost determination, the refrigerant is passed through the bypass refrigerant flow path, and the heat medium is supplied to the heating heat medium flow path and the bypass heat medium flow path. Defrost operation is performed. Thereby, unnecessary defrost operation is not performed.

It is a lineblock diagram showing roughly the whole air-conditioning system concerning a first embodiment. It is a block diagram which shows the control system of an air conditioning system same as the above. It is a flowchart of the refrigerating cycle heating operation in an air conditioning system same as the above. It is a figure which shows the relationship between the coefficient of performance in a refrigerating cycle in the air conditioning system same as the above, and a heating load. It is a flowchart in the heat pump apparatus side of the heat-medium heating operation in an air conditioning system same as the above. It is a flowchart in the hot water supply apparatus side of the heat-medium heating operation in an air conditioning system same as the above. It is a flowchart of the heating operation in an air conditioning system same as the above. It is a defrost operation control flowchart in an air conditioning system same as the above.

  The present disclosure relates to an air conditioning system, and more particularly to an air conditioning system including a heat pump device and a hot water supply device. Hereinafter, a first embodiment of an air conditioning system according to the present disclosure will be described with reference to FIGS.

  As shown in FIG. 1, the air conditioning system 1 includes a heat pump device 2, a hot water supply device 3, and a control unit 10 (see FIG. 2).

  As shown in FIG. 1, the heat pump device 2 includes a compressor 21, an outdoor-side refrigerant heat exchanger 22, an expansion mechanism 23, and an indoor-side refrigerant heat exchanger 24, and constitutes a refrigeration cycle.

  The heat pump device 2 includes an outdoor unit 201 and an indoor unit 202. The outdoor unit 201 includes devices such as a casing (not shown), a compressor 21, an outdoor refrigerant heat exchanger 22, an expansion mechanism 23, a four-way valve 25, and a blower 26 that are accommodated in the casing. Have.

  The expansion mechanism 23 is configured by a capillary tube, an electronic expansion valve, or the like. One end of the flow path of the expansion mechanism 23 is connected to one end of the flow path of the outdoor refrigerant heat exchanger 22 via the refrigerant flow path 27. The outdoor refrigerant heat exchanger 22 is disposed in the middle of an outdoor air flow path (not shown) in the outdoor unit 201. The casing of the outdoor unit 201 has an outside air intake port (not shown) and an outlet port (not shown), and an outside air flow path is formed between the intake port and the outlet port. A fan as the blower 26 is further disposed in the middle of the outside air flow path.

  The other end of the flow path of the outdoor refrigerant heat exchanger 22 is connected to the first port 251 of the four-way valve 25 via the refrigerant flow path 27. The second port 252 of the four-way valve 25 is connected to one end of the flow path of the compressor 21 via the refrigerant flow path 27. The other end of the flow path of the compressor 21 is connected to the third port 253 of the four-way valve 25 via the refrigerant flow path 27. The refrigerant flow path 27 connected to the other end of the flow path of the expansion mechanism 23 and the refrigerant flow path 27 connected to the fourth port 254 of the four-way valve 25 are led out from the outdoor unit 201 and passed to the indoor unit 202. be introduced.

  The indoor unit 202 includes devices such as a casing (not shown), the indoor-side refrigerant heat exchanger 24, the indoor-side heat medium heat exchanger 33, and the blower 28 that are accommodated in the casing. However, the indoor heat medium heat exchanger 33 is an element that constitutes the air conditioning system 1, but is not an element that constitutes the heat pump device 2.

  The casing of the indoor unit 202 has an indoor air intake port (not shown) and a blow-out port (not shown), and an indoor flow path (not shown) is formed between the intake port and the blow-out port. In the middle of the indoor flow path, a fan as the blower 28, the indoor heat medium heat exchanger 33, and the indoor refrigerant heat exchanger 24 are arranged in this order from the intake port side to the outlet port side. .

  One end of the flow path of the indoor side refrigerant heat exchanger 24 is connected to the fourth port 254 of the four-way valve 25 via the refrigerant flow path 27. The other end of the flow path of the indoor refrigerant heat exchanger 24 is connected to the other end of the flow path of the expansion mechanism 23 via the refrigerant flow path 27.

  The four-way valve 25 has a state in which the first port 251 and the second port 252 communicate with each other and the third port 253 and the fourth port 254 communicate with each other, and the first port 251 and the third port 253 communicate with each other. It is possible to arbitrarily switch to one of the states in which the second port 252 and the fourth port 254 communicate with each other.

  In addition, a three-way valve 291 is disposed in a portion of the refrigerant flow path 27 between the expansion mechanism 23 and the indoor-side refrigerant heat exchanger 24. In addition, the three-way valve 292 and the refrigerant heat medium heat exchanger 15 are disposed in a portion of the refrigerant flow path 27 between the indoor refrigerant heat exchanger 24 and the four-way valve 25.

  The three ports of the three-way valve 291 are connected so as to communicate with the expansion mechanism 23, the indoor-side refrigerant heat exchanger 24, and the three-way valve 292 via the refrigerant flow path 27. The three ports of the three-way valve 292 are connected to the indoor-side refrigerant heat exchanger 24, the refrigerant heat medium heat exchanger 15, and the three-way valve 291 via the refrigerant flow path 27, respectively.

  By switching between the three-way valve 291 and the three-way valve 292, the refrigerant becomes the compressor 21, the four-way valve 25, the outdoor-side refrigerant heat exchanger 22, the expansion mechanism 23, the three-way valve 291, the indoor-side refrigerant heat exchanger 24, and the three-way valve 292. The refrigerant heat medium heat exchanger 15, the four-way valve 25, and the compressor 21 can be configured as a refrigeration cycle refrigerant flow path that allows the refrigerant to flow in this order or in the reverse order.

  In addition, by switching between the three-way valve 291 and the three-way valve 292, the refrigerant is converted into the compressor 21, the four-way valve 25, the outdoor refrigerant heat exchanger 22, the expansion mechanism 23, the three-way valve 291, the three-way valve 292, and the refrigerant heat medium heat exchange. The bypass refrigerant flow path that does not flow through the indoor-side refrigerant heat exchanger 24 can be configured by flowing the condenser 15, the four-way valve 25, and the compressor 21 in this order or in the reverse order.

  The three-way valve 291 and the three-way valve 292 constitute a refrigerant channel switching device 29 that switches to either the refrigeration cycle refrigerant channel or the bypass refrigerant channel.

As shown in FIG. 2, the control unit 10 controls the heat pump device 2. The control unit 10 includes, for example, a microcomputer, and controls the operation of each element by executing a program stored in a storage medium such as a ROM (Read Only Memory). Specifically, the control unit 10 is configured such that the amount of refrigerant transported by the compressor 21 per unit time (l / s), the unit time by the blower devices 26 and 28 disposed in the outdoor unit 201 and the indoor unit 202. The air volume per unit (m ³ / s) and switching of the four-way valve 25 can be controlled.

  With this heat pump device 2, a cooling operation and a heating operation can be selectively performed. As shown in FIG. 1, during the cooling operation, the four-way valve 25 is in a state where the first port 251 and the second port 252 communicate with each other and the third port 253 and the fourth port 254 communicate with each other. As a result, a compressor 21, an outdoor refrigerant heat exchanger 22 (condenser), an expansion mechanism 23, an indoor refrigerant heat exchanger 24 (evaporator), and a refrigeration cycle refrigerant flow path that reaches the compressor 21 again are formed. Then, the cooling operation by the refrigeration cycle is performed.

  Further, during the heating operation, the four-way valve 25 is in a state in which the first port 251 and the third port 253 communicate with each other and the second port 252 and the fourth port 254 communicate with each other. As a result, the compressor 21, the indoor refrigerant heat exchanger 24 (condenser), the expansion mechanism 23, the outdoor refrigerant heat exchanger 22 (evaporator), and the refrigeration cycle refrigerant flow path that reaches the compressor 21 again are formed. Then, heating operation by the refrigeration cycle is performed. In the heat pump device 2, the cooling operation and the heating operation by the refrigeration cycle are performed under the control of the control unit 10.

  Such a heat pump device 2 is widely known in the past, and various devices can be used as appropriate and are not particularly limited. For example, the heat pump device 2 may have a device such as an accumulator as appropriate.

  In the first embodiment, the air conditioning system 1 includes a hot water supply device 3. The hot water supply device 3 includes a heat source unit 31, a heat medium, a heat medium flow path 32, an indoor heat medium heat exchanger 33, and a heat source control unit 30 (see FIG. 2).

  The heat source unit 31 heats the heat medium. In the first embodiment, the heat source unit 31 is configured by a fuel cell. The fuel cell may constitute a hot water storage type so-called cogeneration system or may be used alone. Heat generated in the fuel cell is applied to the heat medium via a heat exchanger (not shown). In addition, when a fuel cell comprises a cogeneration system, energy efficiency is high. For this reason, it is preferable that the heat source part 31 is comprised by the fuel cell which comprises a cogeneration system.

  In the middle of the heat medium flow path 32, a heat source unit 31, a transport device 34 including a pump, a valve 35 including a flow rate adjusting valve or a solenoid valve, a refrigerant heat medium heat exchanger 15, a three-way valve 361, An indoor heat medium heat exchanger 33 and a three-way valve 362 are arranged. As described above, the indoor-side heat medium heat exchanger 33 is arranged in the indoor flow path in the casing of the indoor unit 202. The hot water supply device 3 including the indoor heat medium heat exchanger 33 constitutes the heat applying device 12 that applies heat to the air flowing through the indoor flow path in the casing of the indoor unit 202. By using the hot water supply device 3 as the heat application device 12, the followability is improved.

  As shown in FIG. 2, the heat source control unit 30 controls the heat source unit 31, the transport device 34, the valve 35, and the heat medium flow switching device 36 (three-way valve 361 and three-way valve 362). The heat source control unit 30 includes, for example, a microcomputer, and controls the operation of each element by executing a program stored in a storage medium such as a ROM. Specifically, the heat source control unit 30 can control the amount of heat per unit time generated by the heat source unit 31 and applied to the heat medium flowing through the heat medium flow path 32.

  The three ports of the three-way valve 361 are connected to the refrigerant heat medium heat exchanger 15, the indoor heat medium heat exchanger 33, and the three-way valve 362 via the heat medium flow path 32. The three ports of the three-way valve 362 are connected to the indoor heat medium heat exchanger 33, the valve 35, and the three-way valve 361 via the heat medium flow path 32.

  By switching between the three-way valve 361 and the three-way valve 362, the heat medium becomes the heat source unit 31, the transport device 34, the valve 35, the three-way valve 362, the indoor heat medium heat exchanger 33, the three-way valve 361, and the refrigerant heat medium heat exchanger. 15, the heating-heat-medium flow path which flows the heat-source part 31 in this order can be comprised.

  By switching between the three-way valve 361 and the three-way valve 362, the heat medium passes through the heat source unit 31, the transport device 34, the valve 35, the three-way valve 362, the three-way valve 361, the refrigerant heat medium heat exchanger 15, and the heat source unit 31 in this order. Both the bypass heat medium flow path and the heating heat medium flow path that flow through and do not flow through the indoor heat medium heat exchanger 33 can be configured. In other words, in this state, in the three-way valve 362, the heat medium flowing from the upstream side branches toward both the indoor-side heat medium heat exchanger 33 and the three-way valve 361. In the three-way valve 361, the heat medium that has flowed from the upstream three-way valve 362 and the indoor heat medium heat exchanger 33 joins.

  The three-way valve 361 and the three-way valve 362 switch heat between a state where the heat medium flows through the heating heat medium flow path and a state where the heat medium flows through both the heating heat medium flow path and the bypass heat medium flow path. The medium flow path switching device 36 is configured.

  The refrigerant heat medium heat exchanger 15 performs heat exchange between the bypass refrigerant flow path and the heat medium flow path. Specifically, the primary flow path of the refrigerant heat medium heat exchanger 15 is disposed between the four-way valve 25 and the three-way valve 292 of the refrigerant flow path 27. The secondary side flow path of the refrigerant heat medium heat exchanger 15 is disposed between the heat source section 31 of the heat medium flow path 32 and the three-way valve 361.

  In the first embodiment, the air conditioning system 1 further includes a communication device (not shown) that performs communication between the control unit 10 and the heat source control unit 30. By the communication device, the control unit 10 and the heat source control unit 30 can transmit and receive each other wirelessly or by wire. The control unit 10 can control the hot water supply device 3 by communicating with the heat source control unit 30 via the communication device.

  Note that such communication devices are widely known in the past, and various devices can be used as appropriate and are not particularly limited.

  The suction temperature detection unit 11 detects the suction temperature Ts (° C.) on the indoor side in the heat pump device 2 (that is, the temperature of the air in the air-conditioning target space). The suction temperature detection unit 11 is disposed in the vicinity of the intake port of the indoor flow path in the casing of the indoor unit 202. The suction temperature Ts information detected by the suction temperature detection unit 11 is received by the control unit 10.

  In the first embodiment, the outside air temperature detection unit 14 that detects the outside air temperature To (° C.) is disposed in the vicinity of the intake port of the outside air passage in the casing of the outdoor unit 201. The outside air temperature To information detected by the outside air temperature detector 14 is received by the controller 10. In addition, although the suction temperature detection part 11 and the external temperature detection part 14 are mainly comprised by the thermistor, various temperature sensors other than the thermistor can be utilized suitably and are not specifically limited.

The control unit 10 controls the heat pump device 2 to perform the heating operation. In the heating operation, the control unit 10 performs control so that the suction temperature Ts becomes the indoor target temperature Ta (° C.). The indoor target temperature Ta is a generally comfortable temperature such as 18 ° C., for example. In the first embodiment, the air conditioning system 1 includes an operation unit 13. The user can arbitrarily set the indoor target temperature Ta and the air volume Qa (m ³ / s) blown from the blowout port of the indoor unit 202 by operating the operation unit 13. Information on the indoor target temperature Ta and the air volume Qa input from the operation unit 13 is received by the control unit 10.

  In the first embodiment, in the heating operation, the control unit 10 performs feedback control so that the suction temperature Ts falls within a predetermined temperature range including the indoor target temperature Ta. The predetermined temperature range is a temperature range between an allowable upper limit temperature Tu (° C.) that is equal to or higher than the indoor target temperature Ta and an allowable lower limit temperature Tl (° C.).

  The allowable upper limit temperature Tu is a temperature that is appropriately determined by, for example, Tu = indoor target temperature Ta + 5. Further, the allowable lower limit temperature Tl is a temperature that is appropriately determined by, for example, setting the indoor target temperature Ta-5 or the indoor target temperature Ta. The allowable upper limit temperature Tu and the allowable lower limit temperature Tl are not particularly limited with respect to the indoor target temperature Ta, but satisfy Tl <Tu.

  The controller 10 adjusts the number of revolutions per unit time of the motor included in the compressor 21 to control the amount of refrigerant transported. Further, the control unit 10 adjusts the number of rotations per unit time of the motor of the blower 28 disposed in the indoor unit 202 to control the air volume Qa blown from the blowout port of the casing of the indoor unit 202. Further, the control unit 10 controls the amount of air flowing through the outdoor air flow path of the outdoor unit 201 by adjusting the number of rotations per unit time of the motor included in the blower device 26 disposed in the outdoor unit 201.

  The controller 10 can selectively execute a refrigeration cycle heating operation and a heat medium heating operation as the heating operation. In the refrigeration cycle heating operation, the control unit 10 drives the heat pump device 2 and does not drive the hot water supply device 3. That is, in the refrigeration cycle heating operation, the control unit 10 drives the heat pump device 2, but stops the transfer device 34 of the hot water supply device 3, so that the indoor heat medium heat exchanger 33 is placed in the casing of the indoor unit 202. Heat is not applied to the air flowing through the indoor flow path. The heat medium heating operation will be described later. First, the refrigeration cycle heating operation will be described with reference to FIG.

  When the refrigeration cycle heating operation is started, the control unit 10 reads and sets the indoor target temperature Ta and the air volume Qa input from the operation unit 13 in (S1).

  In (S2), the control unit 10 sets the allowable upper limit temperature Tu and the allowable lower limit temperature Tl based on the indoor target temperature Ta.

  In (S3), the control unit 10 starts detecting the suction temperature Ts by the suction temperature detection unit 11.

  In (S4), the control unit 10 drives the compressor 21, the blower device 26 of the outdoor unit 201, and the blower device 28 of the indoor unit 202. When the compressor 21 and the blowers 26 and 28 are driven, a refrigeration cycle is established and the heat pump device 2 is driven, and the suction temperature Ts rises.

  In (S5), the control unit 10 determines whether or not the suction temperature Ts exceeds the allowable upper limit temperature Tu. If the suction temperature Ts does not exceed the allowable upper limit temperature Tu, the process returns to (S5). If the suction temperature Ts exceeds the allowable upper limit temperature Tu, the process proceeds to (S6).

  In (S6), the control part 10 stops the compressor 21 and the air blowers 26 and 28, and complete | finishes a refrigerating cycle heating operation.

  The stop of the heating operation (all heating operations including the refrigeration cycle heating operation and the heat medium heating operation) is always accepted, and when the stop of the heating operation is input by the operation unit 13, the control unit 10 Stop heating operation.

By the way, in the refrigerating cycle heating operation by the heat pump device 2, the heating load W (W) is based on the air volume Qa, the indoor target temperature Ta, and the suction temperature Ts.
W = Qa × (Ta−Ts) × A (Formula 1)
Is required. A in (Expression 1) is a constant determined for each heat pump device 2.

  The relationship shown in FIG. 4 exists between this heating load W and a coefficient of performance (hereinafter referred to as COP) in the refrigeration cycle. Here, Wmin (W) is the minimum value of the heating load W, and is mainly the minimum throttle load determined based on the minimum limit transport amount of the refrigerant transported by the compressor 21 and the outside air temperature To. The minimum limit transport amount is mainly determined by the lower limit value of the number of rotations per unit time of the motor included in the compressor 21.

  Wmax (W) is the maximum value of the heating load W, and is determined mainly based on the maximum limit transport amount of the refrigerant transported by the compressor 21 and the outside air temperature To. The maximum limit transport amount is mainly determined by the upper limit value of the number of rotations per unit time of the motor included in the compressor 21.

  In addition, in the relationship shown in FIG. 4, since the specific value of heating load W and COP is decided for every heat pump apparatus 2, description about a specific value is abbreviate | omitted.

  As shown in FIG. 4, when the heating load at which COP is maximized is Wcmax (W), the range where the upper limit is Wcmax + α1 (W) and the lower limit is Wcmax−α2 (W) is the refrigeration cycle load range. Let it be Z1. Here, α1 and α2 are appropriately determined depending on how wide various allowable ranges are taken from the viewpoint of COP and energy efficiency.

  If the refrigeration cycle heating operation is performed when the heating load W is within the refrigeration cycle load range Z1, the COP and the energy efficiency are preferable. Further, if the refrigeration cycle heating operation is performed when the heating load W is outside the refrigeration cycle load range Z1, COP and energy efficiency are low, which is not preferable.

  Therefore, in the air conditioning system, the range outside the refrigeration cycle load range Z1 is set as the heat medium heating load range Z2, and the heating medium heating operation is performed when the heating load W is within the heat medium heating load range Z2. The control unit 10 grasps the refrigeration cycle load range Z1 and the heat medium heating load range Z2 in advance.

  In the heat medium heating operation, the control unit 10 does not drive the heat pump device 2 and drives the hot water supply device 3. That is, in the heat medium heating operation, the control unit 10 does not drive the compressor 21 and the air blower 28 of the heat pump device 2 and drives the hot water supply device 3 so that the indoor heat medium heat exchanger 33 is connected to the indoor unit 202. Control is performed so as to apply heat to the air flowing through the indoor flow path in the casing.

  The heat medium heating operation will be described with reference to FIGS. 5 and 6. In the heating medium heating operation, the heating medium is the heating heating medium flow path described above, that is, the heat source unit 31, the transfer device 34, the valve 35, the refrigerant heat medium heat exchanger 15, the three-way valve 362, and the indoor heat medium heat exchanger 33. The three-way valve 361 and the heat source 31 are sequentially passed (see FIG. 1).

  As shown in FIG. 5, when the heating medium heating operation is started, the control unit 10 reads and sets the indoor target temperature Ta and the air volume Qa input from the operation unit 13 in (S11).

  In (S12), the control unit 10 sets the allowable upper limit temperature Tu and the allowable lower limit temperature Tl based on the indoor target temperature Ta.

  In (S13), the control unit 10 starts detection of the suction temperature Ts by the suction temperature detection unit 11.

  In (S14), the control unit 10 drives the blower 28 of the indoor unit 202. Even if the blower 28 is driven, the refrigeration cycle is not established because the compressor 21 and the blower 26 of the outdoor unit 201 are not driven, and the heat pump device 2 is not driven.

  In (S15), the control part 10 calculates | requires the heating load W based on Qa, Ts, Ta, and (Formula 1).

  In (S16), the control part 10 transmits the signal which requests | requires the heat medium which provides the heat | fever for heating load W to the air which flows through an indoor flow path to the heat source control part 30 via a communication apparatus. As a result, the amount of heat applied to the air flowing through the indoor flow path does not become insufficient or excessive, and the amount can be made appropriate.

  In response to (S16), as shown in FIG. 6, the control by the heat source control unit 30 on the hot water supply device 3 side starts.

  In (S <b> 21), the heat source control unit 30 is based on the temperature and amount of the heat medium that flows toward the indoor heat medium heat exchanger 33 and the temperature of the heat medium that returns from the indoor heat medium heat exchanger 33. Thus, the replenishment heat amount ΔJ (W) necessary for applying heat corresponding to the heating load W to the air flowing through the indoor flow path of the heat medium is obtained.

  Does the heat source control unit 30 have, as data, the relationship between the temperature and amount of the heat medium that flows toward the indoor heat medium heat exchanger 33 and the temperature of the heat medium that returns from the indoor heat medium heat exchanger 33? Or it is grasped by calculating. The heat source control unit 30 has a relationship between the temperature and amount of the heat medium that flows toward the indoor heat medium heat exchanger 33 and the amount of heat applied to the air that flows through the indoor flow path from the indoor heat medium heat exchanger 33. I know. Mainly due to this relationship, in order for the heat medium to apply heat corresponding to the heating load W to the indoor refrigerant heat exchanger 24, the supplementary heat amount ΔJ applied to the heat medium in the heat source unit 31 is obtained.

  In (S <b> 22), the heat source control unit 30 causes the heat medium heated by the heat source unit 31 and provided with heat for the supplementary heat amount ΔJ to flow toward the indoor heat medium heat exchanger 33.

  The heat source control unit 30 adjusts the flow rate of the heat medium flowing through the heat medium flow path 32 and the supplementary heat amount ΔJ by adjusting the opening degree of the valve 35 or opening and closing the valve 35 (duty control). To do.

  In the hot water supply device 3, when the opening degree of the valve 35 is maximized (when it is opened in the case of the valve 35 made of an on-off valve), the amount of heat that gives heat to the heat medium flowing through the heat medium flow path 32. Has a minimum value. The minimum value of the amount of heat is mainly determined by the lower limit value of the number of rotations per unit time of the motor of the pump as the transport device 34 when the amount of heat generated in the heat source unit 31 is constant. Even when the supplementary heat amount ΔJ is less than the minimum value of the heat amount, the heat source control unit 30 can apply heat for the supplementary heat amount ΔJ that is less than the minimum value to the heat medium by duty control.

  When the heat medium is passed toward the indoor-side heat medium heat exchanger 33 in (S22), the suction temperature Ts (the temperature of the air in the air-conditioning target space) increases.

  As shown in FIG. 5, in (S17), the control unit 10 determines whether or not the suction temperature Ts exceeds the allowable upper limit temperature Tu−ΔT.

  Here, ΔT is a correction value in consideration of an overshoot of an increase in the suction temperature Ts (the temperature of the air in the air-conditioning target space) in the heat medium heating operation. That is, in the heat medium heating operation, even if the hot water supply device 3 is stopped, the heat radiation from the indoor heat medium heat exchanger 33 is not immediately stopped. For this reason, the temperature of the air in the air-conditioning target space rises from the temperature at the time when the hot water supply device 3 is stopped, and overshoot occurs. By correcting the allowable upper limit temperature Tu with the correction value ΔT, it is possible to suppress or prevent the occurrence of overshoot. If overshoot is not considered, ΔT may be set to zero.

  If the suction temperature Ts does not exceed the allowable upper limit temperature Tu−ΔT in (S17), the process returns to (S17). If the suction temperature Ts exceeds the allowable upper limit temperature Tu−ΔT in (S17), the process proceeds to (S18).

  In (S18), the control part 10 stops the air blower 28, transmits the signal which requests | requires the stop of the hot water supply apparatus 3 to the heat source control part 30 via a communication apparatus, and complete | finishes a heat-medium heating operation.

  As shown in FIG. 6, in (S23), when the heat source control unit 30 receives a signal requesting the stop of the hot water supply device 3 transmitted from the control unit 10 in (S18), the heat source control unit 30 is turned on in (S24). Stop and exit.

  Hereinafter, the comprehensive heating operation will be described with reference to FIG. When the heating operation is started, the control unit 10 reads and sets the indoor target temperature Ta and the air volume Qa input from the operation unit 13 in (S31).

  In (S32), the control unit 10 sets the allowable upper limit temperature Tu and the allowable lower limit temperature Tl based on the indoor target temperature Ta.

  In (S <b> 33), the control unit 10 starts detecting the suction temperature Ts by the suction temperature detection unit 11 and the outside air temperature To by the outside air temperature detection unit 14.

  In (S34), the control unit 10 determines whether or not the suction temperature Ts is lower than the allowable lower limit temperature Tl. If the suction temperature Ts is not less than the allowable lower limit temperature Tl, the process returns to (S34). If the suction temperature Ts is lower than the allowable lower limit temperature Tl, the process proceeds to (S35).

  In (S35), the control part 10 calculates | requires the heating load W based on Qa, Ts, Ta, and (Formula 1).

  In (S36), the control unit 10 determines whether or not the heating load W is within the heat medium heating load range Z2. In (S36), if the heating load W is within the load range Z2 for heating medium heating, the process shifts to the heating medium heating operation in (S37) (see FIGS. 5 and 6), and when the heating medium heating operation ends ( Return to S34).

  If the heating load W is not within the heat medium heating load range Z2 in (S36), the process proceeds to the refrigeration cycle heating operation in (S38) (see FIG. 3), and when the refrigeration cycle heating operation is completed, the process proceeds to (S34). Return.

  The indoor target temperature Ta and the air volume Qa set in (S31) may be used in (S1) in the refrigeration cycle heating operation or (S11) in the heat medium heating operation. Further, the allowable upper limit temperature Tu and the allowable lower limit temperature Tl set in (S32) may be used in (S2) in the refrigeration cycle heating operation or (S12) in the heat medium heating operation. Further, the suction temperature Ts detected in (S33) may be used in (S3) in the refrigeration cycle heating operation or (S13) in the heat medium heating operation. Moreover, the heating load W calculated | required in (S35) may be utilized in (S15) in a heat-medium heating operation.

  Next, the defrost operation which removes the frost adhering to the outdoor side refrigerant | coolant heat exchanger 22 or its vicinity (defrost) is demonstrated. The control unit 10 executes the defrost operation control flow shown in FIG. 8 when the heating operation shown in FIG. 7 (including the refrigeration cycle heating operation and the heat medium heating operation) is performed. The defrosting operation control flow is executed in parallel with the heating operation after the heating operation shown in FIG. 7 is started.

  In (S41), the control part 10 performs the defrost determination which determines whether defrost driving | operation is required. In (S41), if it is determined that defrost is required, the process proceeds to (S42). In (S41), when it is not determined that defrost is required, the process returns to (S41). When it is not determined that the defrost is required in (S41), the heating operation shown in FIG. 7 is continued.

  In the defrost determination of (S41), for example, the control unit 10 determines that defrost is necessary when the outside air temperature To is within a predetermined temperature range, or the temperature of the refrigerant returning to the indoor refrigerant heat exchanger 24 is below freezing. In some cases, it is determined that defrost is necessary. The conditions for determining that defrosting is necessary in (S41) are determined as appropriate and are not limited.

  In (S42), the control part 10 determines whether the refrigerating cycle heating operation is performed. In (S42), when it is not determined that the refrigeration cycle heating operation is being performed, the process returns to (S41). In (S42), when it is determined that the refrigeration cycle heating operation is performed, the process proceeds to (S43).

  In (S43), the control unit 10 obtains the supplementary heat amount ΔJ necessary for applying heat for the heating load W and the heat amount ΔJ1 necessary for defrosting when performing heating by the heat medium instead of the refrigeration cycle heating operation. . The supplementary heat quantity ΔJ is obtained in the same manner as the supplementary heat quantity ΔJ is obtained in the heat medium heating operation (S21).

  Moreover, the control part 10 has grasped | ascertained by having as data or calculating the relationship between the outdoor temperature To or the temperature of the refrigerant | coolant which returns to the indoor side refrigerant | coolant heat exchanger 24, etc., and heat quantity (DELTA) J1. Thereby, the control part 10 can obtain | require calorie | heat amount (DELTA) J1 required for a defrost provided to a heat medium.

  In (S44), the control unit 10 causes the refrigerant flow switching device 29 to switch so as to configure a bypass refrigerant flow path. Further, the control unit 10 sets the four-way valve 25 in a state where the first port 251 and the second port 252 communicate with each other and the third port 253 and the fourth port 254 communicate with each other. Thereby, the bypass refrigerant flow path which reaches the compressor 21, the outdoor side refrigerant | coolant heat exchanger 22, the expansion mechanism 23, and the compressor 21 again is comprised.

  Further, the control unit 10 causes the heat medium flow switching device 36 to switch so as to configure the heating heat medium flow path and the bypass heat medium flow path.

  Furthermore, the control part 10 transmits the signal which requests | requires giving the heat | fever for supplementary heat quantity (DELTA) J + heat quantity (DELTA) J1 to a heat medium to the heat source control part 30 via a communication apparatus. In response to this, the heat source control unit 30 performs control so as to apply heat of the supplementary heat amount ΔJ + heat amount ΔJ1 to the heat medium.

  In (S45), the control unit 10 determines whether or not the defrost operation is unnecessary. In (S45), when it is not determined that the defrost is unnecessary, the process returns to (S45) and the defrost operation is continued. In (S45), when it is determined that defrost is unnecessary, the process proceeds to (S46). In (S45), for example, when the temperature of the refrigerant returning to the outdoor unit 201 is equal to the temperature of the refrigerant exiting the outdoor unit 201, it is determined that defrosting is unnecessary. Note that the condition for determining that defrost is unnecessary in (S45) is determined as appropriate and is not limited.

  In (S46), the control unit 10 causes the refrigerant channel switching device 29 to switch so as to configure the refrigeration cycle refrigerant channel. Further, the control unit 10 sets the four-way valve 25 in a state where the first port 251 and the third port 253 communicate with each other and the second port 252 and the fourth port 254 communicate with each other. Thus, the compressor 21, the indoor refrigerant heat exchanger 24 (condenser), the expansion mechanism 23, the outdoor refrigerant heat exchanger 22 (evaporator), and the refrigeration cycle refrigerant flow path reaching the compressor 21 again are configured. Is done.

  Further, the control unit 10 causes the heat medium flow switching device 36 to switch so as to configure the heating heat medium flow path.

  Furthermore, the control part 10 transmits the signal which requests | requires the stop of provision of the heat | fever to a heat medium to the heat source control part 30 via a communication apparatus, complete | finishes a defrost driving | operation, and returns to (S41). In response to this, the heat source control unit 30 stops the conveying device 34, stops applying heat to the heat medium, and ends the defrosting operation.

  In the air conditioning system 1 described above, when the heating load W is within the refrigeration cycle load range Z1, the refrigeration cycle heating operation is performed. When the heating load W is in the heat medium heating load range Z2, the heat medium heating operation is performed.

  When the heating load W is within the refrigeration cycle load range Z1, since the COP is high, the energy efficiency is higher in the refrigeration cycle heating operation than in the heat medium heating operation. Further, when the heating load W is within the heat medium heating load range Z2, the COP is low, so that the heat medium heating operation is more energy efficient than the refrigeration cycle heating operation.

  Further, the defrost operation can be performed while performing the heating operation using the heat medium (heat medium heating operation). As a result, in order to perform defrost operation as in the prior art, cooling is performed in the refrigeration cycle using the outdoor refrigerant heat exchanger 22 as a condenser and the indoor refrigerant heat exchanger 24 as an evaporator. Can be prevented. In addition, with a simple configuration, it is possible to perform the defrost operation while performing the heating medium heating operation.

  In addition, the heat medium necessary for heating the air-conditioning target space is supplied to the indoor heat medium heat exchanger 33 through the heating heat medium flow path. The heat medium necessary for defrosting is supplied to the refrigerant heat medium heat exchanger 15 through a bypass heat medium flow path that does not flow through the indoor heat medium heat exchanger 33. For this reason, the heat required for heating and defrosting of the air-conditioning target space can be efficiently supplied.

  Next, a modification of the first embodiment will be described.

  In the first embodiment, the heat pump apparatus 2 has the four-way valve 25 and can perform both the cooling operation and the heating operation.

  The air conditioning system 1 has the heat source control unit 30 separately from the control unit 10 in the first embodiment, but does not have the heat source control unit 30 different from the control unit 10, and the control unit 10 controls the heat source. The function of the unit 30 may be included.

  The air conditioning system 1 includes the communication device in the first embodiment, but may not include the communication device.

  The indoor target temperature Ta and the air volume Qa can be arbitrarily set by the user in the first embodiment, but may not be arbitrarily set by the user.

  In the first embodiment, the control unit 10 controls the suction temperature Ts to be the indoor target temperature Ta by feedback control in the heating operation. However, the control unit 10 does not necessarily need to be based on feedback control.

  The outside air temperature detection unit 14 may be provided not in the outdoor unit 201 but in a portion located outside the hot water supply device 3.

  The three-way valve 291 and the three-way valve 292 may be accommodated in the outdoor unit 201, may be accommodated in the indoor unit 202, or may not be accommodated in either the outdoor unit 201 or the indoor unit 202. .

  The refrigerant flow switching device 29 is not configured by the three-way valve 291 and the three-way valve 292, but may be configured by a four-way valve or the like, and is not limited.

  The three-way valve 361 and the three-way valve 362 may be accommodated in the outdoor unit 201, may be accommodated in the indoor unit 202, or may not be accommodated in either the outdoor unit 201 or the indoor unit 202. .

  The heat medium flow switching device 36 is not configured by the three-way valve 361 and the three-way valve 362 but may be configured by a four-way valve or the like, and is not limited. The air conditioning system 1 does not necessarily require the heat medium flow switching device 36.

DESCRIPTION OF SYMBOLS 1 Air conditioning system 10 Control part 15 Refrigerant heat medium heat exchanger 2 Heat pump apparatus 21 Compressor 22 Outdoor side refrigerant | coolant heat exchanger 23 Expansion mechanism 24 Indoor side refrigerant | coolant heat exchanger 29 Refrigerant flow path switching apparatus 3 Hot water supply apparatus 31 Heat source part 32 Heat Medium flow path 33 Indoor heat medium heat exchanger 36 Heat medium flow path switching device

Claims (3)

A heat pump device having a compressor, an outdoor refrigerant heat exchanger, an expansion mechanism, and an indoor refrigerant heat exchanger;
A heat medium flow path, an indoor side heat medium heat exchanger provided in the middle of the heat medium flow path for applying heat to the air flowing through the indoor flow path, and a heat medium flowing through the indoor heat medium heat exchanger A water heater having a heat source section for heating,
A controller for controlling the heat pump device and the hot water supply device,
The controller is
Refrigeration cycle heating operation that drives the heat pump device and does not drive the hot water supply device;
Heat medium heating operation that does not drive the heat pump device and drives the hot water supply device,
An air conditioning system capable of
The heat pump device
A refrigeration cycle refrigerant flow path in which a refrigerant flows through the compressor, the outdoor refrigerant heat exchanger, the expansion mechanism, and the indoor refrigerant heat exchanger to form a refrigeration cycle;
A bypass refrigerant flow path through which the refrigerant flows through the compressor, the outdoor refrigerant heat exchanger and the expansion mechanism and does not flow through the indoor refrigerant heat exchanger;
Having a refrigerant flow switching device for switching,
An air conditioning system comprising a refrigerant heat medium heat exchanger that exchanges heat between the bypass refrigerant flow path and the heat medium flow path. The water heater is
A state in which the heating medium flows through the heating source flow path as the heating medium flow path, and circulates through the heat source section and the indoor heat medium heat exchanger;
A bypass heat medium flow path as the heat medium flow path, wherein the heat medium circulates through the heat source section and the refrigerant heat medium heat exchanger but does not flow through the indoor heat medium heat exchanger; A state of passing through both of the heating heat medium flow paths;
Having a heat medium flow switching device for switching,
The air conditioning system according to claim 1, wherein the refrigerant heat medium heat exchanger is arranged to exchange heat between the bypass refrigerant flow path and the bypass heat medium flow path. The controller is
Make a predetermined defrost judgment,
When it is not determined that the defrost is required in the defrost determination, the refrigeration cycle heating operation is performed,
When it is determined that defrost is necessary in the defrost determination,
Switching to the refrigerant flow switching device so as to constitute the bypass refrigerant flow path, allowing the refrigerant to flow through the bypass refrigerant flow path,
The heating medium flow switching device is switched to configure the heating heat medium flow path and the bypass heat medium flow path, and the heat medium flows through the heating heat medium flow path and the bypass heat medium flow path. The air conditioning system according to claim 2.

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