JP2015218940A - Air conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system capable of maintaining indoor comfort, even when defrosting is performed in a heat pump in the case where heating is performed by using the heat pump and a gas furnace.SOLUTION: In an air conditioning system 100 which includes a heat pump unit 6, a gas furnace unit 50 and a common fan 41, heating by the gas furnace unit 50 and heating by the heat pump unit 6 can be performed. In the case where a defrosting start condition is satisfied during heating by the heat pump unit 6, after the gas furnace unit 50 is started and sufficient heating capacity in a furnace heat exchanger 58 is secured, a connection state of a four-way selector valve 72 is switched in the heat pump unit 6, and a defrosting operation is started.

Description

  The present invention relates to an air conditioning system capable of heating a room.

  2. Description of the Related Art Conventionally, there is an air conditioning system that is used in a cold region, for example, and heats a room using a heat pump and a gas furnace as heat source devices.

For example, in Patent Document 1 (Japanese Patent Application Laid-Open No. 64-54160), when the outside air temperature is relatively low, the heating capacity is ensured by operating the gas furnace instead of the heat pump, and the outside air temperature is relatively high. Proposes to control the operation efficiency by operating a heat pump instead of a gas furnace.
JP-A 64-54160

  However, in the example shown in Patent Document 1 as described above, no study has been made on the operation for removing frost attached to the evaporator while the heat pump is driven.

  For this reason, when defrosting is performed by reversing the direction of the refrigerant flowing through the refrigerant circuit in the heat pump and supplying hot gas to the evaporator, the room cannot be heated, resulting in an uncomfortable environment. End up.

  On the other hand, for example, when two heat sources of a heat pump and a gas furnace are switched and used, it is conceivable that the gas furnace is driven when the defrost operation is performed in the heat pump, and indoor heating is engaged.

  However, even if the gas furnace is activated, it is difficult to exert the heating capability instantaneously, and even if the gas furnace is activated at the same time as the defrost operation is started in the heat pump, the capacity to heat the room is temporarily insufficient, which is uncomfortable. There is a risk of becoming.

  The present invention has been made in view of the above points, and the object of the present invention is to maintain indoor comfort even when performing defrosting in a heat pump when heating is performed using a heat pump and a gas furnace. It is possible to provide an air conditioning system.

  An air conditioning system according to a first aspect is an air conditioning system capable of heating a room, and includes a heat pump, a gas furnace, a blower, and a control unit. The heat pump includes a compressor capable of adjusting a driving frequency, a refrigerant radiator, an expansion valve, and a refrigerant evaporator, and circulates the refrigerant. The gas furnace includes a combustion heater. The blower blows air that has passed through the radiator and the heater into the room. The control unit at least controls the gas furnace operation to drive the gas furnace with the heat pump stopped to heat the room according to the set temperature, and drives the heat pump with the gas furnace stopped to the set temperature. And heat pump operation control for heating the room in response. When the control unit satisfies a predetermined defrost start condition during the heat pump operation control, the controller defrosts the refrigerant in the heat pump in a state where the heating capacity satisfies the predetermined capacity condition after starting the gas furnace. Start driving.

  In this air conditioning system, even when defrosting is performed by changing the direction of refrigerant circulation in the heat pump, it is possible to continue heating the room and maintain comfort because the gas furnace is driven.

  The air conditioning system which concerns on a 2nd viewpoint is an air conditioning system which concerns on a 1st viewpoint, Comprising: A control part is a gas until it starts heat pump operation control again from the time of satisfying defrost start conditions during heat pump operation control. Even when the set temperature is exceeded by driving the furnace, the driving state of the gas furnace is maintained.

  In this air conditioning system, even if the room temperature is temporarily exceeded during the defrost operation, the defrosting efficiency of the defrost operation increases as the room temperature rises, and the time required for defrosting by the defrost operation increases. It is possible to shorten the heating time and to restart the heating by the heat pump operation control at an early stage.

  The air conditioning system which concerns on a 3rd viewpoint is an air conditioning system which concerns on a 1st viewpoint or a 2nd viewpoint, Comprising: From the time of satisfying defrost start conditions during heat pump operation control, until a heat pump operation control is started again. During this time, the compressor drive frequency is not increased.

  In this air conditioning system, after the defrost start condition is satisfied, even if the set temperature is not reached, the drive frequency of the heat pump compressor is not increased so that the defrost operation can be started at an early stage. It becomes possible.

  An air conditioning system according to a fourth aspect is the air conditioning system according to any one of the first aspect to the third aspect, and the control unit is configured to supply the refrigerant in the heat pump when a predetermined defrost end condition is satisfied during the defrost operation. The gas furnace is stopped after reversing the circulation direction and setting the heat pump operation control.

  In this air conditioning system, even when the defrost is finished and the gas furnace is stopped, the heat pump is in a driven state, so that it is possible to continue heating the room and maintain comfort.

  In the air conditioning system according to the first aspect, indoor comfort can be maintained even when defrosting is performed.

  In the air conditioning system according to the second aspect, heating by heat pump operation control can be restarted at an early stage.

  In the air conditioning system according to the third aspect, it becomes possible to make it possible to start defrosting operation at an early stage.

  In the air conditioning system according to the fourth aspect, indoor comfort can be maintained even when the defrost is completed and the gas furnace is stopped.

It is the schematic which shows the example of installation to the building of the air system which concerns on this embodiment. It is a schematic block diagram of the air conditioning system which concerns on this embodiment. It is a block block diagram of the air conditioning system which concerns on this embodiment. It is a process flowchart in the case of performing defrost operation at the time of heating operation by a heat pump unit.

  Hereinafter, an outdoor unit of a refrigeration apparatus according to the present invention will be described in detail with reference to the drawings.

(1) Installation Example of Air Conditioning System 100 FIG. 1 is a schematic diagram illustrating an example in which the air conditioning system 100 according to the present embodiment is installed on a building 1. FIG. 2 is a schematic configuration diagram of a circuit and the like of the air conditioning system 100. FIG. 3 is a block configuration diagram of the air conditioning system 100.

  The building 1 in the example in which the air conditioning system 100 is installed is a house having a first room 2a and a second room 2b on the first floor, a third room 2c and a fourth room 2d on the second floor, a basement 2e, and a ceiling back 2f. is there.

  Among these, the heat pump gas furnace integrated unit 30 mentioned later is installed in the basement 2e. Moreover, the outdoor unit 70 which is a part of the heat pump unit 6 described later is installed outside the building 1.

  The conditioned air produced by the heat pump gas furnace integrated unit 30 in the basement 2e passes through the air supply duct 31 provided so as to extend from the air outlet side of the heat pump gas furnace integrated unit 30. It is supplied to the room 2b, the third room 2c, and the fourth room 2d, respectively. Specifically, the air supply duct 31 is configured such that the side opposite to the air outlet side of the heat pump gas furnace integrated unit 30 is branched into a plurality of parts, and the first outlet branch part 31a which is a part of the branch part is provided. The second blowout branch portion 31b, which is located in the first room 2a and is part of the branch portion, is located in the second chamber 2b, and the third blowout branch portion 31c that is part of the branch portion is The 4th blowing branch part 31d which is located in the 3rd room 2c and is a part of a branch part is located in the 4th room 2d.

  Further, the air to be harmonized by the heat pump gas furnace integrated unit 30 is collected from each of the first room 2a, the second room 2b, the third room 2c, and the fourth room 2d via the return air duct 39. Specifically, the return air duct 39 is configured such that the side opposite to the suction port side of the heat pump gas furnace integrated unit 30 is branched into a plurality of parts, and the first suction branch part 39a which is a part of the branch part is provided. The second suction branch part 39b, which is located in the first room 2a and is part of the branch part, is located in the second room 2b, and the third suction branch part 39c which is part of the branch part is The fourth suction branch part 39d, which is located in the third room 2c and is a part of the branch part, is located in the fourth room 2d.

(2) Schematic configuration of air-conditioning system 100 The air-conditioning system 100 is a system for producing temperature-controlled air and supplying it to the air-conditioning target space. The fan unit 40, the heat pump unit 6, the gas furnace unit 50, The control interface 10, the indoor temperature sensor 62, the main controller 20, the above-described air supply duct 31, the return air duct 39, and the like are included.

  Among these, the heat pump unit 6 includes a utilization unit 60 and an outdoor unit 70 that are connected to each other via a liquid refrigerant communication pipe 76 and a gas refrigerant communication pipe 77.

  As shown in FIG. 2, the fan unit 40, the gas furnace unit 50, and the utilization unit 60 of the heat pump unit 6 are integrated to form a heat pump gas furnace integrated unit 30.

  The heat pump gas furnace integrated unit 30 has a housing 30a. Inside the housing 30a, the utilization unit 60 and the gas furnace unit 50 of the fan unit 40 and the heat pump unit 6 are accommodated in a straight line. In the present embodiment, the fan unit 40 is disposed at the lowermost position, and the gas furnace unit 50 and the utilization unit 60 are disposed side by side above the fan unit 40 in this order.

  The control interface 10 is not particularly limited, but is provided in the first room 2a of the building 1 in the present embodiment. The control interface 10 receives input of operation setting information such as a set temperature from the user. Furthermore, the control interface 10 receives instructions for starting and stopping the operation of the air conditioning system 100 from the user. Moreover, the control interface 10 has a display unit (not shown) for displaying information on the driving state. The control interface 10 is communicably connected to the main controller 20 disposed in the basement 2e.

  Although the indoor temperature sensor 62 is not particularly limited, in the present embodiment, the indoor temperature sensor 62 is disposed in the first room 2a of the building 1 and is located in the temperature of the first room 2a (a place away from the first outlet branch portion 31a and the first suction branch portion 39a). Temperature). The room temperature sensor 62 is connected to the main controller 20 disposed in the basement 2e, and can inform the main controller 20 of the current temperature of the first room 2a.

  The main controller 20 is based on the information received from the user via the control interface 10, the indoor temperature detected by the indoor temperature sensor 62, the outdoor temperature detected by the outdoor air temperature sensor 78b of the outdoor unit 70, and the like. The gas furnace unit 50, the fan unit 40, etc. are controlled. The main controller 20 has a CPU 20a and a memory 20b. The CPU 20a performs various controls based on data and the like that the memory 20b has. The memory 20b stores information on the set temperature received from the user via the control interface 10.

  Hereinafter, the heat pump unit 6, the gas furnace unit 50, the fan unit 40, and the like will be described.

(3) Heat pump unit 6
As shown in FIG. 2, the heat pump unit 6 is a vapor compression type air conditioner configured to include a use unit 60, an outdoor unit 70, a liquid refrigerant communication pipe 76, and a gas refrigerant communication pipe 77. The heat pump unit 6 of the present embodiment is configured to be able to execute both the cooling operation and the heating operation by switching.

  The utilization unit 60 and the outdoor unit 70 have a portion connected via a liquid refrigerant communication pipe 76 and a portion connected via a gas refrigerant communication pipe 77.

  The usage unit 60 includes a usage-side heat exchanger 61 and a usage-side heat exchange temperature sensor 63. The use side heat exchanger 61 exchanges heat between the refrigerant passing through the inside and the air passing through the outside. The use side heat exchanger 61 is arranged so as to fill a passage extending in the vertical direction inside the housing 30a of the heat pump gas furnace integrated unit 30. A liquid refrigerant communication pipe 76 is connected to one end in the use side heat exchanger 61, and a gas refrigerant communication pipe 77 is connected to the other end. The use side heat exchanger temperature sensor 63 detects the temperature of the refrigerant flowing inside the use side heat exchanger 61. The temperature information detected by the use side heat exchange temperature sensor 63 is transmitted to the main controller 20 and the outdoor unit controller 79.

  The outdoor unit 70 is installed outdoors in the building 1, and includes a compressor 71, a four-way switching valve 72, an outdoor heat exchanger 73, an outdoor fan 74, an electric expansion valve 75, an outdoor heat exchanger temperature sensor 78a, and an outdoor air temperature sensor. 78b, and an outdoor unit controller 79. The compressor 71 has an inverter machine that is driven using electrical energy. The compressor 71 can change a capacity | capacitance by changing the drive frequency of this inverter machine. The outdoor unit controller 79 is connected to the compressor 71 and has an inverter control unit 71a for controlling the drive frequency of the inverter machine. The outdoor heat exchanger 73 performs heat exchange between the outdoor air supplied by the outdoor fan 74 and the refrigerant flowing inside. The outdoor fan 74 has an outdoor fan motor 74a for controlling the air volume. The outdoor fan motor 74a is controlled by an outdoor unit controller 79. The electric expansion valve 75 can change the amount of refrigerant passing therethrough by changing the valve opening. The compressor 71, the four-way switching valve 72, the outdoor heat exchanger 73, the electric expansion valve 75, and the use-side heat exchanger 61 are connected to each other to form a refrigerant circuit 6a in which the refrigerant circulates. .

  The four-way switching valve 72 can switch the refrigerant flow direction in the refrigerant circuit 6a between the heating operation state and the cooling operation state or the defrost operation state by switching the connection state. In the heating operation state (connection state shown by the solid line in FIG. 2), the compressor 71 is driven to circulate the refrigerant in the refrigerant circuit 6a, whereby the discharge side of the compressor 71, the four-way switching valve 72, the use side heat. The refrigerant flows in the order on the suction side of the exchanger 61, the electric expansion valve 75, the outdoor heat exchanger 73, the four-way switching valve 72, and the compressor 71, and the outdoor heat exchanger 61 functions as a refrigerant radiator. The heat exchanger 73 is caused to function as a refrigerant heater. Thereby, heat can be taken from the air outside the building 1 and supplied into the building 1. In the cooling operation state (connection state indicated by a dotted line in FIG. 2), the compressor 71 is driven to circulate the refrigerant in the refrigerant circuit 6a, whereby the discharge side of the compressor 71, the four-way switching valve 72, the outdoor heat exchange. Refrigerant 73, electric expansion valve 75, use-side heat exchanger 61, four-way switching valve 72, and refrigerant 71 in this order, let the refrigerant flow in the order, and the use-side heat exchanger 61 functions as a refrigerant heater. The heat exchanger 73 is caused to function as a refrigerant radiator. Thereby, heat can be taken from the air in the building 1 to be released to the outside of the building 1. The connection state of the four-way switching valve 72 is switched by the outdoor unit controller 79. In the defrost operation state, similarly to the cooling operation state, the four-way switching valve 72 is configured such that the discharge side of the compressor 71 is connected to the outdoor heat exchanger 73 side, and the suction side of the compressor 71 is connected to the use side heat exchanger 61. The connected state is established. By driving the compressor 71 in this connected state and circulating the refrigerant in the refrigerant circuit 6a, the discharge side of the compressor 71, the four-way switching valve 72, the outdoor heat exchanger 73, the electric expansion valve 75, the use side heat. The refrigerant flows in the order of the exchanger 61, the four-way switching valve 72, and the suction side of the compressor 71, supplies high-temperature and high-pressure refrigerant to the outdoor heat exchanger 73, and melts frost adhering to the outdoor heat exchanger 73. Lend. The connection state of the four-way switching valve 72 is switched by the outdoor unit controller 79.

  The outdoor heat exchange temperature sensor 78 a detects the temperature of the refrigerant flowing inside the outdoor heat exchanger 73. The temperature information detected by the outdoor heat exchange temperature sensor 78a is transmitted to the outdoor unit controller 79.

  The outside air temperature sensor 78b detects the temperature of the outdoor air before passing through the outdoor heat exchanger 73. The temperature information detected by the outside air temperature sensor 78b is transmitted to the outdoor unit controller 79.

  In the cooling operation state, the outdoor unit controller 79 receives a command from the main controller 20, and the detected temperature of the indoor temperature sensor 62 is set to the set temperature based on the detected temperature of the indoor temperature sensor 62 and the detected temperature of the outside air temperature sensor 78b. In addition to controlling the outdoor fan motor 74a and the electric expansion valve 75 so as to be close to each other, the inverter control unit 71a controls the drive frequency of the compressor 71 to adjust the cooling capacity.

  In the heating operation state, the outdoor unit controller 79 receives a command from the main controller 20, and the detected temperature of the indoor temperature sensor 62 is set based on the detected temperature of the indoor temperature sensor 62 and the detected temperature of the outside air temperature sensor 78b. The outdoor fan motor 74a and the electric expansion valve 75 are controlled so as to be close to each other, and the driving frequency of the compressor 71 is controlled by the inverter control unit 71a to adjust the heating capacity.

  In the defrost operation state, the outdoor heat is controlled by controlling the valve opening degree of the electric expansion valve 75 and the drive frequency of the compressor 71 by the inverter control unit 71a regardless of whether the detected temperature of the indoor temperature sensor 62 approaches the set temperature. The frost adhering to the exchanger 73 is actively melted. At this time, the outdoor fan motor 74a is stopped.

  In addition, the heat pump unit 6 is difficult to operate efficiently and to fully demonstrate its ability, such as when the outdoor heat exchanger 73 lacks the ability to evaporate the refrigerant, such as when the outside air temperature is extremely low. Although there is an outside air temperature range, when the outside air temperature is higher than the extremely low temperature, it is possible to operate with better COP (Coefficient of Performance) than the gas furnace unit 50. Device. Here, the COP is a value obtained by dividing the heating or cooling ability Q by the consumed energy L for obtaining the ability Q.

(4) Gas furnace unit 50
As shown in FIG. 2, the gas furnace unit 50 includes a gas furnace controller 51, a fuel control valve 54, a furnace fan 56, a combustion chamber 57, a furnace heat exchanger 58, an exhaust pipe 59, and the like. It is a type heater.

  The gas furnace controller 51 is communicably connected to the main controller 20, and controls the amount of fuel that passes through the fuel adjustment valve 54 and the furnace fan motor 56 a based on a command from the main controller 20.

  The combustion chamber 57 is provided with a gas burner 57a. Fuel gas is supplied to the combustion chamber 57 via the combustion gas supply pipe 53, and air is supplied via the air supply pipe 55. Here, although it does not specifically limit as a combustion gas, For example, natural gas etc. are used.

  The combustion gas supply pipe 53 is provided with a fuel adjustment valve 54 for adjusting the amount of combustion gas supplied to the combustion chamber 57. Combustion gas is supplied to the combustion chamber 57 by opening the opening of the fuel control valve 54. The valve opening degree of the fuel adjustment valve 54 is also controlled by the gas furnace controller 51 as described above.

  A furnace fan 56 is provided between the air supply pipe 55 and the combustion chamber 57. When the furnace fan 56 is rotationally driven, air is sent to the combustion chamber 57. The furnace fan 56 includes a variable-speed furnace fan motor 56a. The furnace fan motor 56a is also controlled by the gas furnace controller 51 as described above.

  In this way, the combustion gas and air supplied to the combustion chamber 57 are mixed and burned by the gas burner 57a to generate high-temperature gas. This hot gas is sent to the furnace heat exchanger 58.

  The furnace heat exchanger 58 is disposed in the housing 30 a of the heat pump gas furnace integrated unit 30 and vertically below the use unit 60. The furnace heat exchanger 58 exchanges heat between the heating gas passing through the inside and the air passing outside through the housing 30a of the heat pump gas furnace integrated unit 30 upward. Thereby, the air that has passed through the outside of the furnace heat exchanger 58 is warmed.

  The exhaust pipe 59 is connected to the end of the furnace heat exchanger 58 opposite to the combustion chamber 57 side. An exhaust header 59 a is provided at a connection portion of the exhaust pipe 59 with the furnace heat exchanger 58.

(5) Fan unit 40
As shown in FIG. 2, the fan unit 40 is arranged below the furnace heat exchanger 58 of the utilization unit 60 and the gas furnace unit 50 in the housing 30 a of the heat pump gas furnace integrated unit 30. And a common fan 41 for generating an air flow from bottom to top.

  In the common fan 41, the furnace heat exchanger 58 of the gas furnace unit 50 and the use side heat exchanger 61 of the use unit 60 are arranged in a straight line in the flow path in the housing 30a of the heat pump gas furnace integrated unit 30. Yes. Thereby, it is possible to supply an air flow to both the furnace heat exchanger 58 of the gas furnace unit 50 and the use side heat exchanger 61 of the use unit 60 only by driving the common fan 41. . That is, it is not necessary to separately provide a fan corresponding to the furnace heat exchanger 58 of the gas furnace unit 50 and a fan corresponding to the use side heat exchanger 61 of the use unit 60.

  The common fan 41 includes a variable speed common fan motor 41a, and can adjust the amount of air passing through the housing 30a of the heat pump gas furnace integrated unit 30. The common fan motor 41a is controlled by the main controller 20.

(6) Control of the air conditioning system 100 In the air conditioning system 100, the main controller 20 controls the cooling operation, the heating operation, and the defrost operation.

(6-1) Control of cooling operation In the air conditioning system 100, during the cooling operation, the operation of the gas furnace unit 50 is stopped, and the heat pump unit 6 is driven in a state where the four-way switching valve 72 is switched to the cooling operation state. Then, by driving the common fan 41 of the fan unit 40, cold air is supplied to the first to fourth rooms 2a to 2d.

  Here, in the compressor 71, the outdoor fan motor 74a, the electric expansion valve 75, and the common fan motor 41a of the heat pump unit 6, the detected temperature of the indoor temperature sensor 62 approaches the set temperature based on the detected temperature of the indoor temperature sensor 62. In this way, the main controller 20 and the outdoor unit controller 79 are controlled.

(6-2) Control of heating operation In the air conditioning system 100, during the heating operation, either one of the gas furnace unit 50 and the heat pump unit 6 is used to create warm air and drive the common fan 41 of the fan unit 40. Hot air is supplied to the first to fourth rooms 2a to 2d.

  Here, when it is difficult to operate the heat pump unit 6 efficiently or when the outside air temperature becomes extremely low or the heating load is large to the extent that it is difficult to fully display the capacity, the heat pump unit 6 is stopped, and the gas furnace heating operation in which only the gas furnace unit 50 is driven is performed. On the other hand, the gas furnace unit 50 is stopped and the heat pump unit 6 only when the heat pump unit 6 can be operated efficiently and the outside temperature is sufficient to fully display the capacity or the heating load is small. The heat pump heating operation driven by is performed. This extremely low temperature, that is, an outside air temperature that is so low that it is difficult to operate the heat pump unit 6 efficiently or to fully exert its capacity is predetermined as the high reference temperature T1 and stored in the memory 20b. Stored. Here, although the temperature is lower than the extremely low temperature (high reference temperature T1), it is possible to operate the heat pump unit 6 more efficiently as compared with the case where the gas furnace unit 50 is operated. There are cases where is small. In this way, when the heating load is small, the temperature serving as a reference for prioritizing the operation of the heat pump unit 6 is determined in advance as the low reference temperature T2 that is lower than the high reference temperature T1 and stored in the memory 20b. Yes. In addition, when the heat pump unit 6 performs the heating operation, the four-way switching valve 72 is driven in a state of being switched to the heating operation state.

  Here, during the gas furnace heating operation, the fuel control valve 54 and the furnace fan motor 56a are configured so that the main controller 20 and the furnace temperature sensor 62 and the furnace fan motor 56a are set to approach the set temperature based on the detected temperature of the indoor temperature sensor 62. It is controlled by the gas furnace controller 51.

  Further, during the heat pump heating operation, the compressor 71, the outdoor fan motor 74a, the electric expansion valve 75, and the common fan motor 41a are configured such that the detected temperature of the indoor temperature sensor 62 approaches the set temperature based on the detected temperature of the indoor temperature sensor 62. In this way, the main controller 20 and the outdoor unit controller 79 are controlled. Specifically, when the detected value of the indoor temperature sensor 62 is less than the set temperature, control such as increasing the drive frequency of the compressor 71 is performed.

(6-3) Control of Defrost Operation In the air conditioning system 100, heating is performed by using the heat pump unit 6 instead of the gas furnace unit 50 to generate warm air and supplying the warm air to the first to fourth rooms 2 a to 2 d by the common fan 41. When the operation is performed, when a predetermined defrost start condition is satisfied, the connection state of the four-way switching valve 72 of the heat pump unit 6 is switched to defrost the frost attached to the outdoor heat exchanger 73. Is done.

  In this defrost operation, the compressor 71 is driven by switching the connection state of the four-way switching valve 72 of the heat pump unit 6 to a connection state similar to the connection state at the time of the cooling operation, so that the outdoor heat exchanger 73 is heated at a high temperature. Supply high-pressure refrigerant. Thereby, the frost adhering to the outer surface of the outdoor heat exchanger 73 can be melted.

  Here, in the defrost operation, the connection state of the four-way switching valve 72 of the heat pump unit 6 becomes the same connection state as in the cooling operation, so that the use side heat exchanger 61 cannot function as a refrigerant radiator. . For this reason, during the defrost operation, the gas furnace unit 50 is driven to create warm air, and the common fan 41 of the fan unit 40 is driven to continue supplying hot air to the first to fourth rooms 2a to 2d. Yes.

  In the defrost operation, when a predetermined defrost end condition is satisfied, it is assumed that frost adhering to the outdoor heat exchanger 73 has melted, and the connection state of the four-way switching valve 72 of the heat pump unit 6 is switched to perform heating. Return to the connection state during operation.

  As described above, the defrost operation is started every time the predetermined defrost start condition is satisfied while the heating operation is being performed, and is ended every time the predetermined defrost end condition is satisfied.

(7) Switching control between heating operation and defrost operation As described above, the defrost operation is started whenever the predetermined defrost start condition is satisfied and the predetermined defrost end condition is satisfied during the heating operation. However, since the use side heat exchanger 61 of the heat pump unit 6 does not function as a refrigerant radiator during defrost operation, the gas furnace unit 50 is driven instead to create warm air, and the first to fourth rooms 2a. The supply of warm air to ˜2d is continued.

  Here, when the gas furnace unit 50 is started, the gas furnace controller 51 opens the fuel control valve 54 provided in the combustion gas supply pipe 53 while driving the furnace fan motor 56 a of the furnace fan 56. By increasing the degree, the combustion gas is sent to the combustion chamber 57 via the combustion gas supply pipe 53, and the air is sent to the combustion chamber 57 via the air supply pipe 55. In the combustion chamber 57, combustion gas and air are mixed. Here, the mixed gas of combustion gas and air reaches a combustion concentration, and is burned by the gas burner 57a to generate high temperature gas. The hot gas generated in this way is sent to the furnace heat exchanger 58 by driving the furnace fan 56. Through the above steps, it is possible to start warming the air passing outside the furnace heat exchanger 58 by the high-temperature gas flowing inside the furnace heat exchanger 58. As described above, when the gas furnace unit 50 is activated, from the time when the gas furnace controller 51 receives the activation instruction to the time when the air actually passing outside the furnace heat exchanger 58 is in a warmed state. There is a time lag.

  On the other hand, in the air conditioning system 100 of the present embodiment, the main controller 20 is in a state where the heating capacity by the furnace heat exchanger 58 of the gas furnace unit 50 is ensured at the time when the defrost operation is started in the heat pump unit 6. Thus, the gas furnace unit 50 is started to be started from a time before the defrost operation is started. As a result, even if there is a time lag from when the gas furnace unit 50 starts to start until the air passing through the outside of the furnace heat exchanger 58 is actually warmed, the first to first defrost operations are started. It is possible to continue the supply of warm air to the fourth rooms 2a to 2d.

  Specifically, as shown in the flowchart of FIG. 4, switching control between the heating operation and the defrost operation is performed. Below, the process from the state in which heating operation is performed is demonstrated.

  In step S10, the main controller 20 determines whether or not a predetermined defrost start condition is satisfied. Here, the predetermined defrost start condition is set in advance as a temperature condition in which frost appears to be attached to the outdoor heat exchanger 73, and is not particularly limited, but in the present embodiment, the outdoor heat exchange temperature sensor 78a. Is detected on the condition that the temperature detected by is less than or equal to a predetermined defrost start temperature.

  In step S11, the main controller 20 starts the gas furnace controller 51 to start the gas furnace unit 50 without starting the defrost operation in the outdoor unit 70. Specifically, the gas furnace controller 51 drives the furnace fan motor 56a of the furnace fan 56 and increases the valve opening of the fuel control valve 54 provided in the combustion gas supply pipe 53, thereby supplying the combustion gas. Combustion gas is sent to the combustion chamber 57 via the pipe 53, and air is sent to the combustion chamber 57 via the air supply pipe 55. In the combustion chamber 57, the mixed gas of combustion gas and air reaches the combustion concentration and is burned by the gas burner 57 a, and the generated high temperature gas is sent to the furnace heat exchanger 58 by driving the furnace fan 56. Here, the driving state of the common fan motor 41a is maintained.

  Here, after starting the gas furnace unit 50 by satisfying a predetermined defrost start condition, the main controller 20 drives the gas furnace unit 50 to drive the first to fourth rooms 2a to 2d. Even if the temperature exceeds the set temperature, the driving state of the gas furnace unit 50 is maintained without weakening.

  In addition, the outdoor unit controller 79 is assumed to be in a state where it does not satisfy the set temperature of the first to fourth rooms 2a to 2d until the defrost operation is started after the predetermined defrost start condition is satisfied. Also, the drive frequency of the compressor 71 is limited so as not to increase.

  In step S12, the gas furnace controller 51 determines whether or not the gas furnace unit 50 has finished starting. Here, it is determined whether or not the furnace heat exchanger 58 of the gas furnace unit 50 is activated and can fully exhibit the heating capacity. Specifically, although not particularly limited, for example, it may be determined whether or not a predetermined startup time has elapsed since the start of startup of the gas furnace unit 50, and the temperature around the furnace heat exchanger 58 may be determined. It may be determined whether or not a predetermined temperature has been reached. If it is determined that the startup has been completed, the gas furnace controller 51 informs the main controller 20 accordingly.

  In step S13, the main controller 20 determines that the activation of the gas furnace unit 50 has ended, and the gas furnace unit 50 alone can sufficiently exhibit the heating capacity, and causes the outdoor unit controller 79 to start the defrost operation. Here, the outdoor unit controller 79 performs pressure equalization processing of the refrigerant pressure on the upstream side and the downstream side of the compressor 71 of the refrigerant circuit 6a, and the connection state of the four-way switching valve 72 is determined on the use side on the discharge side of the compressor 71. The heating operation state connected to the heat exchanger 61 is switched to the cooling operation state where the discharge side of the compressor 71 is connected to the outdoor heat exchanger 73. In such a connected state, the compressor 71 is driven, and the high-temperature and high-pressure refrigerant is sent to the frosting outdoor heat exchanger 73. In the defrost operation, the outdoor fan 74 is stopped, but the driving of the common fan 41 is continued in order to continue supplying hot air to the first to fourth rooms 2a to 2d.

  In step S14, the outdoor unit controller 79 determines whether or not the defrost end condition is satisfied. The defrost end condition is a condition that the frost adhering to the outdoor heat exchanger 73 seems to have melted and is not particularly limited, but in the present embodiment, the use side heat exchange sensor 63 detects the use side heat exchange. It is determined whether or not the temperature of the refrigerant flowing through the vessel 61 is equal to or higher than a predetermined defrost end temperature, and whether or not a predetermined defrost time has elapsed since the start of the defrost operation. Here, when either condition is satisfied, the outdoor unit controller 79 determines that the frost adhering to the outdoor heat exchanger 73 is almost melted, and proceeds to step S15.

  In step S15, the outdoor unit controller 79 switches the connection state of the four-way switching valve 72 of the heat pump unit 6 to return to the connection state during the heating operation, assuming that the defrost termination condition is satisfied. Here, in the refrigerant circuit 6a of the heat pump unit 6, until the pressure of the high-pressure refrigerant on the discharge side of the compressor 71 reaches a predetermined pressure, the outdoor unit controller 79 has a drive frequency of the compressor 71 equal to or lower than a predetermined frequency. Limit the increase in frequency to be maintained at

  In step S16, the outdoor unit controller 79 determines whether or not the pressure of the high-pressure refrigerant on the discharge side of the compressor 71 has reached a predetermined pressure, and if it has reached, proceeds to step S17. In addition, it can be set as the condition where the heating capability in the heat pump unit 6 was ensured by raising a high pressure in this way.

  In step S17, the gas furnace controller 51 stops driving the gas furnace unit 50, and returns to step S11 to repeat.

(8) Features of this embodiment (8-1)
In the air conditioning system 100 according to the present embodiment, both the gas furnace unit 50 that can cope with a situation where the outside air temperature is extremely low or the heating load is large, and the heat pump unit 6 with high operating efficiency can be selectively used. .

  For this reason, load processing can be performed even when the outside air temperature is extremely low or the heating load is large, and efficient operation is performed when the outside air temperature is not extremely low or the heating load is small. Is possible.

(8-2)
Further, in the air conditioning system 100, even when it takes time until the heating capability can be sufficiently exhibited after the gas furnace unit 50 starts to start, when the defrost operation is started in the heat pump unit 6. The heating capacity in the furnace heat exchanger 58 of the gas furnace unit 50 is already sufficiently secured.

  For this reason, it becomes possible to perform the defrost operation of the heat pump unit 6 while maintaining the warmth of the room comfortably.

(8-3)
Further, in the air conditioning system 100, during the defrosting operation, even if the gas furnace unit 50 is driven and the temperature exceeds the set temperature of the first to fourth rooms 2a to 2d, the gas furnace unit 50 is driven. The condition is maintained without weakening.

  For this reason, even if the temperature of each room temporarily exceeds the set temperature during the defrost operation, the defrost efficiency of the outdoor heat exchanger 73 in the defrost operation can be increased by increasing the indoor temperature. .

  Thereby, the time required for defrosting by the defrost operation can be shortened, and the heating operation by the heat pump unit 6 can be restarted at an early stage.

(8-4)
In the air conditioning system 100, the outdoor unit controller 79 temporarily does not reach the set temperature of the first to fourth rooms 2a to 2d after the predetermined defrost start condition is satisfied and before the defrost operation is started. Even if it becomes a state, it restrict | limits so that the drive frequency of the compressor 71 may not rise.

  For this reason, it is possible to facilitate the pressure equalization process that is performed before switching the connection state of the four-way switching valve 72 when starting the defrost operation, and to shorten the time required for starting the defrost operation. It becomes possible.

(8-5)
Further, in the air conditioning system 100 according to the present embodiment, the gas furnace unit 50 includes the fuel adjustment valve 54 that adjusts the supply amount of the combustion gas to the gas burner 57. For this reason, in the state where the gas furnace heating operation is performed, it is possible to adjust the heating capacity in detail while processing a large heating load.

  And in the air conditioning system 100 which concerns on this embodiment, the heat pump unit 6 has the compressor 71 which can adjust a capability by inverter control. For this reason, in the state where the heat pump heating operation is performed, it is possible to adjust the heating capacity in detail while performing an efficient operation.

(8-6)
In the air conditioning system 100 according to the present embodiment, the amount of air that passes through the use-side heat exchanger 61 of the heat pump unit 6 and the amount of air that passes through the furnace heat exchanger 58 of the gas furnace unit 50 are 1 It can be adjusted by two common fans 41. For this reason, it is not necessary to separately provide a fan for the heat pump unit 6 and a fan for the gas furnace unit 50, and the apparatus can be made compact.

(9) Other Embodiments In the above embodiment, an example of the embodiment of the present invention has been described. However, the above embodiment is not intended to limit the present invention, and is not limited to the above embodiment. The present invention naturally includes aspects appropriately modified without departing from the spirit of the present invention.

(9-1)
In the above embodiment, the case where the fan unit 40, the utilization unit 60, and the gas furnace unit 50 are arranged in this order from the bottom has been described.

  However, the arrangement order of these elements is not particularly limited. For example, the fan unit may be disposed on the downstream side of the utilization unit or the gas furnace unit, or may be disposed between the utilization unit and the gas furnace unit. Further, the arrangement of the utilization unit and the gas furnace unit may be different from that in the above embodiment in the air flow direction, and the utilization unit may be arranged on the downstream side of the gas furnace unit.

  In addition, for example, the use unit and the gas furnace unit are not provided side by side in the air flow direction, and a flow path switching mechanism or the like is provided, so that air is supplied to only one side of the use unit and the gas furnace unit. You may be comprised so that it may pass.

(9-2)
In the above embodiment, the case where the pressure equalization process for switching the connection state of the four-way switching valve 72 is performed when the defrost operation is started has been described.

  However, the processing to be performed when starting the defrost operation is not limited to this. For example, the liquid refrigerant accumulated in the use side heat exchanger 61 functioning as a condenser is connected to the suction side of the compressor 71. Thus, a process of moving the liquid refrigerant to another location may be performed so that the compressor 71 does not suck the liquid refrigerant. For example, when the refrigerant circuit includes a receiver, the process of moving the liquid refrigerant to another location may be a process of moving the liquid refrigerant to the receiver.

  In the air conditioning system having a heat pump and a gas furnace, the air conditioning system according to the present invention can perform a defrost operation while maintaining indoor comfort when performing a heating operation using a heat pump and a gas furnace. It is particularly useful.

1 Building 2a-2d 1st-4th Room 2e Basement 6 Heat Pump Unit (Heat Pump)
20 Main controller (control unit)
30 Heat pump gas furnace integrated unit 40 Fan unit (blower)
41 Common fan 41a Common fan motor 50 Gas furnace unit (gas furnace)
51 Gas furnace controller (control unit)
52 Combustion unit 53 Fuel tank 55 Air intake 56 Furnace fan 57 Gas burner 58 Furnace heat exchanger (heater)
60 Usage unit 61 Usage side heat exchanger (evaporator, radiator)
62 Indoor temperature sensor 63 Use side heat exchange temperature sensor 70 Outdoor unit 71 Compressor 72 Four-way switching valve 73 Outdoor heat exchanger (radiator, evaporator)
74 Outdoor Fan 74a Outdoor Fan Motor 75 Electric Expansion Valve 76 Liquid Refrigerant Communication Pipe 77 Gas Refrigerant Communication Pipe 78a Outdoor Heat Exchange Temperature Sensor 78b Outdoor Air Temperature Sensor 79 Outdoor Unit Controller (Control Unit)
100 Air conditioning system

JP-A 64-54160

Claims (4)

An air conditioning system (100) capable of heating a room,
A heat pump (6) including a compressor (71) capable of adjusting a driving frequency, a refrigerant radiator (73, 61), an expansion valve (75), and an evaporator (61, 73), and circulating the refrigerant;
A gas furnace (50) including a heater by combustion;
A blower (41) for blowing air that has passed through the radiator and the heater into the room;
At least the gas furnace operation control in which the gas furnace is driven in a state where the heat pump is stopped and the room is heated according to a set temperature, and the heat pump is driven in the state where the gas furnace is stopped and the setting is performed. A control unit (20, 79, 51) for performing heat pump operation control for heating the room according to the temperature;
With
The controller, when a predetermined defrost start condition is satisfied during the heat pump operation control, after the gas furnace is started and the heating capacity satisfies the predetermined capacity condition, the refrigerant circulation direction in the heat pump Start defrost operation to reverse
Air conditioning system. When the control unit exceeds the set temperature by driving the gas furnace from the time when the defrost start condition is satisfied during the heat pump operation control until the heat pump operation control is started again. Even so, the driving state of the gas furnace is maintained.
The air conditioning system according to claim 1. The control unit does not increase the drive frequency of the compressor until the heat pump operation control is started again after the defrost start condition is satisfied during the heat pump operation control.
The air conditioning system according to claim 1 or 2. The controller, when a predetermined defrost end condition is satisfied during the defrost operation, reverses the circulation direction of the refrigerant in the heat pump and sets the gas furnace after the heat pump operation control is performed. To stop,
The air conditioning system according to any one of claims 1 to 3.

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