JP6768883B2 - Ventilation system and defrost control method - Google Patents

Description

The present invention relates to a ventilator and a defrost control method performed in the ventilator.

Conventionally, a device including a ventilation unit including a total heat exchanger and a refrigeration cycle for adjusting the temperature of air supplied from the ventilation unit into a room has been known. In the total heat exchanger, total heat (sensible heat and latent heat) is exchanged between the outdoor air and the indoor air. For example, Japanese Patent Application Laid-Open No. 5-141747 (Patent Document 1) describes a total heat exchanger according to the need for ventilation in the defrosting operation of the heat source machine side heat exchanger (evaporator) included in the refrigeration cycle. An air conditioner that can determine whether or not to exchange indoor air with outdoor air via the air conditioner is disclosed. According to the air conditioner, when it is necessary to give priority to ventilation in the room, for example, when cigarette smoke or oil smoke is generated in the room, the evaporator is performed while ventilating the room. Defrosting operation can be performed.

Japanese Patent Application Laid-Open No. 5-141747

In a ventilator equipped with a total heat exchanger and a refrigeration cycle, when heat is exchanged between the low temperature outdoor air and the high temperature indoor air in the total heat exchanger, the indoor air is cooled below the dew point and dew condensation occurs. May occur. Depending on the temperature of the outdoor air, the inside of the total heat exchanger may be below freezing and frost may occur. Therefore, in the ventilation device, it is necessary to perform a defrosting operation not only on the heat exchanger that functions as an evaporator in the heating operation but also on the total heat exchanger.

The conditions under which frost is generated (frost formation conditions) can differ between the evaporator and the total heat exchanger. The frost condition of the evaporator can be, for example, a condition related to the temperature of the outdoor air. On the other hand, the frosting conditions of the total heat exchanger are, for example, conditions related to the difference between the temperature of the outdoor air and the temperature of the indoor air, or conditions related to the difference between the absolute humidity of the outdoor air and the absolute humidity of the indoor air. can do. Therefore, the timing at which the frost formation condition is satisfied may differ between the total heat exchanger and the evaporator. As a result, the defrosting operation for the evaporator and the defrosting operation for the total heat exchanger may be started at different timings.

In the defrosting operation for the total heat exchanger, the frost generated in the total heat exchanger is melted, so that the suction of the low temperature outdoor air is suppressed and the high temperature indoor air is continuously discharged. That is, in the defrosting operation for the total heat exchanger, ventilation through the total heat exchanger cannot be sufficiently performed. Further, in the defrosting operation for the evaporator, in order to heat the heat exchanger that was functioning as the evaporator, for example, the circulation direction of the refrigerant in the refrigeration cycle is reversed so that the heat exchanger functions as a condenser. In this case, the heat exchanger (condenser) that heated the air supplied to the room until the defrosting operation is performed functions as an evaporator, so that the cooled air is cooled when the air supply to the room is continued. Will be supplied indoors. Since the air from the total heat exchanger cannot be adjusted to the temperature desired by the user and supplied into the room, the supply of air into the room is suppressed. As a result, even in the defrosting operation for the evaporator, ventilation through the total heat exchanger cannot be sufficiently performed. Therefore, it may not be possible to secure a sufficient amount of air supply to the ventilation device during the time period during which at least one of the defrosting operation for the total heat exchanger and the defrosting operation for the evaporator is performed.

If the defrosting operation for the total heat exchanger and the defrosting operation for the evaporator are started at different timings, the time zone during which both the defrosting operation for the total heat exchanger and the defrosting operation for the evaporator are performed is It may be shorter and the time zone during which one is being performed may be longer. As a result, the time period during which the amount of air supplied from the ventilation device decreases may be extended. However, in the air conditioner disclosed in Japanese Patent Application Laid-Open No. 5-141747 (Patent Document 1), the defrosting operation for the total heat exchanger is not considered.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is a time period during which the amount of air supplied from the ventilation device is reduced in a ventilation unit including a total heat exchanger and a refrigeration cycle. Is to shorten.

The ventilation device according to one aspect of the present invention outputs the air from the first ventilation hole from the second ventilation hole and the air from the third ventilation hole from the fourth ventilation hole. The ventilation device includes a first ventilation path, a first ventilation device, a second ventilation path, a second ventilation device, a first heat exchanger, a refrigeration cycle device, and a control device. The first ventilation passage connects the first ventilation hole and the second ventilation hole. The first ventilation device blows air so that air is directed from the first ventilation hole to the second ventilation hole in the first ventilation passage. The second ventilation passage connects the third ventilation hole and the fourth ventilation hole. The second ventilation device blows air so that air is directed from the third ventilation hole to the fourth ventilation hole in the second ventilation passage. The first heat exchanger is arranged between the first ventilation hole and the second ventilation hole, and is arranged between the third ventilation hole and the fourth ventilation hole, and is arranged with the air passing through the first ventilation passage. Sensible heat and latent heat are exchanged with the air passing through the second ventilation path. Refrigeration cycle equipment includes a second heat exchanger, a compressor, a third heat exchanger, and an expansion valve. The refrigerant circulates in the first circulation direction in the order of the second heat exchanger, the compressor, the third heat exchanger, and the expansion valve. The control device performs a defrosting operation on each of the first heat exchanger and the second heat exchanger. The refrigeration cycle device further includes a flow path switching device. The flow path switching device switches the direction in which the refrigerant circulates to the first circulation direction or the second circulation direction opposite to the first circulation direction. The third heat exchanger exchanges heat between the air and the refrigerant between the first heat exchanger and the second ventilation hole. The control device performs the first defrosting operation on the first heat exchanger after the first frosting condition is satisfied. The control device performs a second defrosting operation on the second heat exchanger after the second frosting condition is satisfied. If the second frost condition is satisfied after the first frost condition is satisfied and before the first defrost operation is performed, the control device removes both the first heat exchanger and the second heat exchanger. Perform the third defrosting operation to frost. The control device performs the third defrosting operation when the first defrosting condition is satisfied after the second defrosting condition is satisfied and before the second defrosting operation is performed. The control device reduces the amount of air blown per unit time of the first blower device in the first defrosting operation. In the second defrosting operation, the control device controls the flow path switching device to switch the refrigerant circulation direction from the first circulation direction to the second circulation direction, and the unit time of each of the first blower and the second blower. Reduce the amount of air blown per hit. In the third defrosting operation, the control device controls the flow path switching device to switch the refrigerant circulation direction from the first circulation direction to the second circulation direction, and reduces the amount of air blown per unit time of the first blower. , The amount of air blown per unit time of the second blower is set to be equal to or greater than the standard amount of air blown.

The defrosting control method according to another aspect of the present invention is performed in a ventilation device that outputs air from the first ventilation hole from the second ventilation hole and outputs air from the third ventilation hole from the fourth ventilation hole. .. The ventilation device includes a first ventilation path, a first ventilation device, a second ventilation path, a second ventilation device, a first heat exchanger, a refrigeration cycle device, and a control device. The first ventilation passage connects the first ventilation hole and the second ventilation hole. The first ventilation device blows air so that air is directed from the first ventilation hole to the second ventilation hole in the first ventilation passage. The second ventilation passage connects the third ventilation hole and the fourth ventilation hole. The second ventilation device blows air so that air is directed from the third ventilation hole to the fourth ventilation hole in the second ventilation passage. The first heat exchanger is arranged between the first ventilation hole and the second ventilation hole, and is arranged between the third ventilation hole and the fourth ventilation hole, and is arranged with the air passing through the first ventilation passage. Sensible heat and latent heat are exchanged with the air passing through the second ventilation path. Refrigeration cycle equipment includes a second heat exchanger, a compressor, a third heat exchanger, and an expansion valve. The refrigerant circulates in the first circulation direction in the order of the second heat exchanger, the compressor, the third heat exchanger, and the expansion valve. The control device performs a defrosting operation on each of the first heat exchanger and the second heat exchanger. The refrigeration cycle device further includes a flow path switching device. The flow path switching device switches the direction in which the refrigerant circulates to the first circulation direction or the second circulation direction opposite to the first circulation direction. The third heat exchanger exchanges heat between the air and the refrigerant between the first heat exchanger and the second ventilation hole. The defrost control method includes a step of performing a first defrost operation on the first heat exchanger after the first frost formation condition is satisfied. The defrosting control method further includes a step of performing a second defrosting operation on the second heat exchanger after the second frosting condition is satisfied. The defrosting control method is that when the second frosting condition is satisfied after the first frosting condition is satisfied and before the first defrosting operation is performed, both the first heat exchanger and the second heat exchanger are satisfied. Further includes a step of performing a third defrosting operation for defrosting. The defrosting control method further includes a step of performing a third defrosting operation when the first defrosting condition is satisfied after the second defrosting condition is satisfied and before the second defrosting operation is performed. The step of performing the first defrosting operation includes a step of reducing the amount of air blown per unit time of the first blower device. The step of performing the second defrosting operation is a step of switching the circulation direction of the refrigerant from the first circulation direction to the second circulation direction by controlling the flow path switching device, and the unit time of each of the first blower and the second blower. Includes a step to reduce the amount of air blown per hit. The step of performing the third defrosting operation is a step of switching the circulation direction of the refrigerant from the first circulation direction to the second circulation direction by controlling the flow path switching device, and reducing the amount of air blown per unit time of the first blower device. This includes a step of causing the second blower to blow air per unit time of the second blower device to a reference air blower amount or more.

In the present invention, the first defrosting operation for the first heat exchanger (total heat exchanger) and the second defrosting operation for the second heat exchanger (evaporator) are started after the respective frosting conditions are satisfied. .. If the other frosting condition is satisfied after one of the frosting conditions is satisfied and before the defrosting operation corresponding to the frosting condition is performed, both the first heat exchanger and the second heat exchanger are satisfied. The third defrosting operation for defrosting is started. By performing such synchronous processing, the time period during which both the defrosting operation for the first heat exchanger and the defrosting operation for the second heat exchanger are performed becomes longer, and one of them is performed. The time zone becomes shorter. As a result, the time period during which the amount of air supplied from the ventilation device is reduced can be shortened, and the comfort of the user can be improved.

It is a figure which shows the flow of the refrigerant in a heating operation. It is a figure which shows the flow of the refrigerant in a cooling operation and a defrosting operation. It is a control block diagram which shows the signal flow in the ventilation apparatus which concerns on Embodiment 1. FIG. It is an external view which shows the outline of the structure of the static total heat exchanger. It is a time chart of the defrosting operation in the comparative example in which the defrosting operation is performed immediately after the frosting condition is satisfied. It is a time chart of the defrosting operation in Embodiment 1. It is a flowchart for demonstrating the synchronous processing of the defrosting operation performed in Embodiment 1. It is a flowchart for demonstrating the process flow of the defrosting operation with respect to the total heat exchanger. It is a flowchart for demonstrating the flow of the process of the defrosting operation for an outdoor heat exchanger. It is a flowchart for demonstrating the process flow of the synchronous defrosting operation. It is a functional block diagram which shows the structure of the ventilation apparatus which concerns on Embodiment 2. FIG. It is a flowchart for demonstrating the flow of the process of the synchronous defrosting operation in Embodiment 2. It is a functional block diagram which shows the structure of the ventilation apparatus which concerns on Embodiment 2. FIG. It is a flowchart for demonstrating the flow of the process of the synchronous defrosting operation in the modification of Embodiment 2. It is a functional block diagram which shows the structure of the ventilation apparatus which concerns on Embodiment 3. It is a figure which also shows the time chart of the power consumption when the frost formation suppression operation is not performed, the target heating capacity of a refrigeration cycle, and the amount of heat recovered by the total heat exchanger. It is a figure which also shows the time chart of the power consumption when the frost formation suppression operation is performed on the total heat exchanger, the target heating capacity of the refrigeration cycle, and the amount of heat recovered by the total heat exchanger. It is also a figure which shows the time chart of the power consumption when the frost formation suppression operation with respect to an outdoor heat exchanger is performed, the target heating capacity of a refrigerating cycle, and the amount of heat recovered of the total heat exchanger. It is a figure which shows the range of the outside air temperature which performs the frost formation suppression operation with respect to the total heat exchanger. It is a figure which shows the range of the temperature difference between the outdoor temperature, which performs the frost formation suppression operation with respect to the outdoor heat exchanger, and the indoor temperature. It is a flowchart for demonstrating the flow of the frost formation suppression cooperation processing in Embodiment 3. It is a flowchart for demonstrating the process flow of the frost formation suppression operation with respect to the total heat exchanger. It is a flowchart for demonstrating the flow of the process of the frost formation suppression operation with respect to an outdoor heat exchanger. It is a functional block diagram which shows the structure of the ventilation apparatus which concerns on Embodiment 4. FIG. It is a flowchart for demonstrating the defrosting suppression process for a rotary total heat exchanger. It is also a figure which shows the time chart of the power consumption when the frost formation suppression operation with respect to a rotary total heat exchanger is performed, the target heating capacity of a refrigeration cycle, and the amount of heat recovered by the total heat exchanger.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In principle, the same or corresponding parts in the drawings are designated by the same reference numerals and the description is not repeated.

Embodiment 1.
1 and 2 are functional block diagrams showing the configuration of the ventilation device 100 according to the first embodiment. The operation mode of the ventilation device 100 includes a heating operation, a cooling operation, and a defrosting operation. FIG. 1 is a diagram showing a flow of refrigerant in a heating operation. FIG. 2 is a diagram showing the flow of the refrigerant in the cooling operation and the defrosting operation. FIG. 3 is a control block diagram showing a signal flow in the ventilation device 100. Hereinafter, the configuration of the ventilation device 100 will be described with reference to FIGS. 1 to 3.

As shown in FIG. 1, the ventilation device 100 includes an outdoor unit 10, a ventilation unit 20, and an integrated controller 30.

The outdoor unit 10 includes a compressor 10a, an outdoor heat exchanger 10b, a four-way valve 10d, an accumulator 10e, an outdoor fan 10g, an outdoor controller 10f, temperature sensors 1b, 10h, 10i, and pressure sensors 10m, 10k. And include.

The ventilation unit 20 has ventilation holes VH1, VH2, VH3, and VH4. The ventilation unit 20 includes a ventilation passage VF1 that connects the ventilation holes VH1 and VH2, and a ventilation passage VF2 that connects the ventilation holes VH3 and VH4. The ventilation unit 20 sucks outdoor air (OA: Outer Air) from the ventilation hole VH1 and outputs air supply (SA: Supply Air) from the ventilation hole VH2 into the room R1. The ventilation unit 20 sucks the return air (RA: Return Air) in the room R1 from the ventilation hole VH3, and outputs the exhaust gas (EA: Exhaust Air) from the ventilation hole VH4 to the outside. The ventilation unit 20 further includes an indoor heat exchanger 20b, an expansion valve 20c, temperature sensors 1c, 20h, 20i, a ventilation controller 20f, an air supply fan 21g, an exhaust fan 22g, and a total heat exchanger 40. Including.

The compressor 10a, the indoor heat exchanger 20b, the expansion valve 20c, and the outdoor heat exchanger 10b constitute a refrigeration cycle device. In the heating operation, the refrigerant circulates in the circulation direction of the compressor 10a, the indoor heat exchanger 20b, the expansion valve 20c, and the outdoor heat exchanger 10b in this order as shown in FIG. In the heating operation, the outdoor heat exchanger 10b functions as an evaporator and the indoor heat exchanger 20b functions as a condenser. The indoor heat exchanger 20b is arranged so as to exchange heat between the air and the refrigerant between the total heat exchanger 40 and the ventilation hole VH2.

As the refrigerant used in the refrigeration cycle, for example, a natural refrigerant such as carbon dioxide, hydrocarbon, or helium can be used. Further, a chlorine-free refrigerant such as HFC410A or HFC407C, or a chlorofluorocarbon-based refrigerant such as R22 or R134a can be used.

The integrated controller 30 transmits a control signal to each of the outdoor controller 10f and the ventilation controller 20f to integrally control the outdoor unit 10 and the ventilation unit 20.

The outdoor heat exchanger 10b evaporates the liquid refrigerant contained in the moist steam and discharges the gas refrigerant to the compressor 10a. In the outdoor heat exchanger 10b, the liquid refrigerant takes heat (heat of vaporization) from the indoor air and evaporates. As the outdoor heat exchanger 10b, for example, a cross-fin type fin-and-tube heat exchanger composed of a heat transfer tube and a large number of fins can be used. The outdoor fan 10g blows air to the outdoor heat exchanger 10b.

The compressor 10a compresses the low-pressure gas refrigerant received from the outdoor heat exchanger 10b, and outputs the high-pressure gas refrigerant to the indoor heat exchanger 20b. The accumulator 10e is connected between the outdoor heat exchanger 10b and the compressor 10a. The accumulator 10e is a tank for storing the liquid refrigerant when the refrigerant from the outdoor heat exchanger 10b passes through the accumulator 10e and preventing the liquid refrigerant from flowing into the compressor 10a.

The four-way valve 10d is controlled by the outdoor controller 10f to switch the direction in which the refrigerant circulates. In the heating operation, the four-way valve 10d forms a flow path so that the refrigerant circulates in the order of the compressor 10a, the indoor heat exchanger 20b, the expansion valve 20c, and the outdoor heat exchanger 10b.

The temperature sensor 1b detects the outdoor temperature and outputs it to the integrated controller 30. As the outdoor temperature, the temperature included in the information such as the weather forecast published on the Internet may be used. The temperature sensor 10h is installed in the pipe between the indoor heat exchanger 20b and the four-way valve 10d, and outputs the detected pipe temperature (refrigerant temperature) to the integrated controller 30. The temperature sensor 10i is installed in the pipe between the expansion valve 20c and the outdoor heat exchanger 10b, and outputs the detected pipe temperature to the integrated controller 30. The pressure sensor 10k is installed near the discharge port of the compressor 10a and outputs the detected refrigerant pressure to the integrated controller 30. The pressure sensor 10m is installed near the suction port of the compressor 10a and outputs the detected refrigerant pressure to the integrated controller 30.

The outdoor controller 10f controls the drive frequency of the compressor 10a to control the amount of refrigerant discharged by the compressor 10a per unit time. The outdoor controller 10f controls the four-way valve 10d to switch the circulation direction of the refrigerant according to the operation mode of the ventilation device.

The outdoor controller 10f adjusts the rotation speed of the outdoor fan 10g to control the amount of air blown per unit time. The outdoor controller 10f has a control unit (not shown) including a processor such as a CPU (Central Processing Unit). The outdoor controller 10f has a storage unit (not shown) including a non-volatile memory such as a flash memory. The storage unit stores, for example, an OS (Operating System) read and executed by a control unit, programs of various applications (for example, a program for controlling defrosting operation), and various data used by the programs. can do.

The indoor heat exchanger 20b receives the high-temperature and high-pressure gas refrigerant from the compressor 10a, condenses it, and discharges the liquid refrigerant to the expansion valve 20c. From the indoor heat exchanger 20b, heat (condensation heat) when the gas refrigerant is condensed into a liquid refrigerant is released. As the indoor heat exchanger 20b, as in the outdoor heat exchanger 10b, for example, a cross-fin type fin-and-tube heat exchanger composed of a heat transfer tube and a large number of fins can be used.

The expansion valve 20c adiabatically expands the liquid refrigerant from the indoor heat exchanger 20b to reduce the pressure, and discharges the liquid refrigerant as wet vapor to the outdoor heat exchanger 10b. The expansion valve 20c includes a stepping motor (not shown) for adjusting the opening degree. As the expansion valve 20c, for example, an electronically controlled expansion valve (LEV: Linear Expansion Valve) can be used.

The total heat exchanger 40 exchanges sensible heat (temperature) and latent heat (humidity) between the outside air OA from the ventilation hole VH1 and the return air RA from the ventilation hole VH3. In the heating operation, the outside air OA is usually low temperature and low humidity air, and the return air is high temperature and high humidity air. Therefore, in the heating operation, the total heat is transferred from the return air RA to the outside air OA in the total heat exchanger 40. The total heat exchanger 40 not only ventilates, but also has a function of recovering the total heat contained in the return air RA, supplying the recovered total heat to the fresh outside air OA, and returning it to the room.

The total heat exchanger 40 is a static total heat exchanger. The static total heat exchanger has a simpler structure than the rotary total heat exchanger described later, and enables miniaturization of the device. As the total heat exchanger 40, for example, the orthogonal flow type total heat exchanger 40A shown in FIG. 4A can be used. In the total heat exchanger 40A, the heat-transmitting and moisture-permeable sheet member 41A and the heat-transmitting and moisture-permeable flow path forming member 42A are alternately laminated. The flow paths formed by the flow path forming members 42A on both sides of the sheet member 41A in the stacking direction are orthogonal to each other. When the outside air OA and the return air RA pass through the total heat exchanger 40A, the total heat is exchanged via the seat member 41A.

The total heat exchanger 40 may be, for example, a countercurrent total heat exchanger 40B as shown in FIG. 4 (b). In the total heat exchanger 40B, there are portions parallel to each other in the flow paths formed by the flow path forming members 42B on both sides of the sheet member 41B in the stacking direction. In this portion, the outside air OA and the return air RA are countercurrents, so that the exchange of total heat is promoted.

With reference to FIG. 1 again, the air supply fan 21g is installed between the total heat exchanger 40 and the ventilation hole VH2 in the ventilation passage VF1 and blows the air from the ventilation hole VH1 toward the ventilation hole VH2. .. The exhaust fan 22g is installed between the total heat exchanger 40 and the ventilation hole VH4 in the ventilation passage VF2, and blows the air from the ventilation hole VH3 toward the ventilation hole VH4.

The temperature sensor 1c is installed between the total heat exchanger 40 and the ventilation hole VH4 in the ventilation path VF2, and outputs the detected temperature to the integrated controller 30. The temperature sensor 20h is installed in the pipe between the compressor 10a and the indoor heat exchanger 20b, and outputs the detected pipe temperature (refrigerant temperature) to the integrated controller 30. The temperature sensor 20i is installed in the pipe between the indoor heat exchanger 20b and the expansion valve 20c, and outputs the detected pipe temperature (refrigerant temperature) to the integrated controller 30.

The ventilation controller 20f controls the rotation speed of each of the air supply fan 21g and the exhaust fan 22g to control the amount of air blown per unit time. The ventilation controller 20f adjusts the opening degree of the expansion valve 20c. The ventilation controller 20f has a control unit (not shown) including a processor such as a CPU (Central Processing Unit). The ventilation controller 20f has a storage unit (not shown) including a non-volatile memory such as a flash memory. The storage unit stores, for example, an OS (Operating System) read and executed by a control unit, programs of various applications (for example, a program for controlling defrosting operation), and various data used by the programs. can do.

In the cooling operation and the defrosting operation, as shown in FIG. 2, a flow path is formed so that the refrigerant circulates in the order of the compressor 10a, the outdoor heat exchanger 10b, the expansion valve 20c, and the indoor heat exchanger 20b. Will be done. In the cooling operation and the defrosting operation, the outdoor heat exchanger 10b functions as a condenser, and the indoor heat exchanger 20b functions as an evaporator.

With reference to FIG. 3, the integrated controller 30 acquires the room temperature from the temperature sensor 1a installed in the room R1, and the outdoor unit via the outdoor controller 10f and the ventilation controller 20f so that the room temperature approaches the target temperature. 10 and the ventilation unit 20 are controlled respectively.

The integrated controller 30 calculates the condensing temperature CT (Condensing Temperature) and the evaporation temperature ET (Evaporating Temperature) from the saturation pressures obtained from the pressure sensors 10k and 10m, respectively. The integrated controller 30 calculates the degree of superheat from the difference between the temperature of the refrigerant flowing out of the evaporator and the evaporation temperature ET. The temperature of the refrigerant flowing out of the evaporator is the temperature from the temperature sensor 10h in the heating operation and the temperature from the temperature sensor 20h in the cooling operation. Further, the integrated controller 30 calculates the degree of supercooling from the difference between the refrigerant temperature flowing out of the condenser and the condensation temperature CT. The temperature of the refrigerant flowing out of the condenser is the temperature from the temperature sensor 20i in the heating operation and the temperature from the temperature sensor 10i in the cooling operation. The integrated controller 30 adjusts the opening degree of the expansion valve 20c, for example, via the ventilation controller 20f, or drives the compressor 10a, for example, via the outdoor controller 10f so that the degree of overheating and the degree of overcooling approach the optimum values. Control the frequency.

The integrated controller 30 controls the compressor 10a, the four-way valve 10d, and the outdoor fan 10g via the outdoor controller 10f. The integrated controller 30 controls the expansion valve 20c, the air supply fan 21g, and the exhaust fan 22g via the ventilation controller 20f. The integrated controller 30, the outdoor controller 10f, and the ventilation controller 20f do not have to be separate controllers, but may be integrated controllers.

When the ventilation device 100 is performing the heating operation, frost may occur in the total heat exchanger 40. When heat exchange is performed between the low temperature outside air OA and the high temperature indoor air return air RA in the total heat exchanger 40, the return air RA may be cooled below the dew point and dew condensation may occur. Depending on the temperature of the outside air OA, the inside of the total heat exchanger 40 may be below freezing and frost may occur. When frost is formed on the total heat exchanger 40, the pressure loss inside the total heat exchanger 40 increases and the amount of air supply decreases. Therefore, in the ventilation device 100, not only the outdoor heat exchanger 10b but also the total heat exchanger 40 is defrosted. The integrated controller 30 performs the defrosting operation of the outdoor heat exchanger 10b when the frost formation condition of the outdoor heat exchanger 10b is satisfied. As frosting conditions for the outdoor heat exchanger 10b, for example, the outdoor air temperature is below the threshold temperature Tset1 (for example, -10 ° C), and the temperature difference between the outdoor temperature and the indoor temperature is the threshold temperature difference ΔT1 (for example, −35 deg). ) The following conditions can be used.

In the defrosting operation for the total heat exchanger 40, in order to melt the frost generated in the total heat exchanger 40, the air supply fan 21 g is stopped, the suction of the low temperature outside air OA is stopped, and the high temperature indoor air is stopped. The discharge of return air RA is continued. The low-temperature outside air OA is suppressed from passing through the total heat exchanger 40, and the high-temperature return air RA passes through the total heat exchanger 40, thereby promoting the melting of frost. Instead of stopping the air supply fan 21g, the rotation speed of the air supply fan 21g may be reduced to reduce the amount of air blown per unit time.

When the ventilation device 100 is performing the heating operation, dew condensation may occur even in the outdoor heat exchanger 10b that functions as an evaporator in the outdoor unit 10 having a low air temperature because the air temperature becomes lower than the dew point. Frost occurs when the outside temperature drops below freezing. When frost is formed on the outdoor heat exchanger 10b, the amount of air passing through the outdoor heat exchanger 10b is reduced, so that the heat exchange efficiency is lowered. Therefore, in the ventilation device 100, when frost is generated in the outdoor heat exchanger 10b, a defrosting operation is performed to melt and remove the frost. The integrated controller 30 performs the defrosting operation of the outdoor heat exchanger 10b when the frost formation condition of the outdoor heat exchanger 10b is satisfied. As the frost formation condition of the outdoor heat exchanger 10b, for example, the condition that the outdoor air temperature is equal to or lower than the threshold temperature Tset2 (for example, 3 ° C.) and the piping temperature is below the freezing point can be used.

With reference to FIG. 2 again, in the defrosting operation for the outdoor heat exchanger 10b, the circulation direction of the refrigerant is set to the opposite direction to the heating operation by switching the four-way valve 10d, and the outdoor heat exchanger 10b functions as a condenser. It is done by letting. In the defrosting operation for the outdoor heat exchanger 10b, the temperature of the outdoor heat exchanger 10b rises because the high-temperature refrigerant from the compressor 10a flows into the outdoor heat exchanger 10b. Further, since the outdoor heat exchanger 10b functions as a condenser, the heat of condensation is released and the temperature around the outdoor heat exchanger 10b rises. As a result, the melting of the frost generated in the outdoor heat exchanger 10b is promoted. In this case, the indoor heat exchanger 20b, which functions as a condenser and heats the air supplied to the room until the defrosting operation is performed, functions as an evaporator. If the air supply to the room is continued, the cooled air will be supplied to the room. Since the air from the total heat exchanger 40 cannot be adjusted to the temperature desired by the user and supplied to the room, the air supply fan 21 g is stopped in the defrosting operation for the outdoor heat exchanger 10b to enter the room. The air supply is stopped.

If the supply of air to the room is stopped and the air from the room is continuously discharged, the pressure inside the room becomes lower than that outside the room, and the pressure inside the room may become negative. Therefore, it is desirable that the exhaust fan 22g is stopped in the defrosting operation for the outdoor heat exchanger 10b. Instead of stopping the air supply fan 21g, the rotation speed of the air supply fan 21g may be reduced to reduce the amount of air blown per unit time. Similarly, the exhaust fan 22 g may reduce the amount of air blown to such an extent that the pressure inside the room is not lower than that outside the room.

The frost formation conditions may differ between the total heat exchanger 40 and the outdoor heat exchanger 10b. Therefore, the timing at which the frost formation condition is satisfied may differ between the total heat exchange outdoor heat exchanger 10b and the total heat exchanger 40. As a result, if the defrosting operation is started immediately after the frost formation condition is satisfied, the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b may be started at different timings.

While the defrosting operation for the outdoor heat exchanger 10b is being performed, the air supply fan 21g and the exhaust fan 22g are stopped, so that the ventilation unit 20 does not sufficiently ventilate and the amount of air supply is reduced. Further, even while the total heat exchanger 40 is being defrosted, the air supply fan 21g is stopped, so that the ventilation unit 20 does not sufficiently ventilate and the amount of air supply is reduced. Therefore, when at least one of the defrosting operation for the outdoor heat exchanger 10b and the defrosting operation for the total heat exchanger 40 is performed, the amount of air supplied from the ventilation unit 20 is reduced.

FIG. 5 is a time chart of the defrosting operation in the comparative example in which the defrosting operation is performed immediately after the frost formation condition is satisfied. FIG. 5A is a time chart showing a time zone in which the total heat exchanger 40 is defrosted. In FIG. 5A, it is assumed that the frost formation condition of the total heat exchanger 40 is satisfied at time Tm1, and the defrosting operation for the total heat exchanger 40 is completed at time Tm3. FIG. 5B is a diagram showing a time chart showing a time zone in which the defrosting operation for the outdoor heat exchanger 10b is performed. In FIG. 5B, it is assumed that the frost formation condition of the outdoor heat exchanger 10b is satisfied at the time Tm2, and the defrosting operation for the outdoor heat exchanger 10b is completed at the time Tm4. During the time period from Tm2 to Tm3 when the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b are simultaneously performed, the amount of air blown per unit time of the exhaust fan 22g is not reduced. It is assumed that the amount of air required to defrost the total heat exchanger 40 is maintained. As shown in FIG. 5, the air is supplied from the ventilation unit 20 from the time Tm1 when the defrosting operation for the total heat exchanger 40 starts to the time Tm4 when the defrosting operation for the outdoor heat exchanger 10b ends. The amount is reduced.

When the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b are started at different timings, both the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b are started. (Time zone from time Tm2 to Tm3) is shortened, and time zone when one of them is performed (time zone from time Tm1 to Tm2 and time zone from time Tm3 to Tm4) May be longer. As a result, the time zone in which the amount of air supply is reduced (the time zone from time Tm1 to Tm4) may become longer.

Therefore, in the first embodiment, in order to shorten the time zone in which the amount of air supply is reduced, the total heat exchange is performed by synchronizing the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b. The time zone during which both the defrosting operation for the vessel 40 and the defrosting operation for the outdoor heat exchanger 10b are performed is lengthened. Specifically, the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b are started at a time after a certain period of time has elapsed from the establishment of the respective frosting conditions. When both the frosting conditions of the total heat exchanger 40 and the frosting conditions of the outdoor heat exchanger 10b are satisfied within the fixed time, the total heat exchanger 40 is set earlier than the respective defrosting operation start times. The synchronous defrosting operation for defrosting both the outdoor heat exchanger 10b and the outdoor heat exchanger 10b is started. Due to such synchronous processing, the time zone in which both the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b are performed becomes longer, and the time zone in which one of them is performed becomes longer. It gets shorter. As a result, the time zone in which the amount of air supply is reduced can be shortened, and the comfort of the user can be improved.

FIG. 6 is a time chart of the defrosting operation according to the first embodiment. FIG. 6A is a time chart showing a time zone in which the defrosting operation for the total heat exchanger 40 is performed. In FIG. 6A, it is assumed that the frost formation condition of the total heat exchanger 40 is satisfied at the time Tm11 and the defrosting operation is performed from the time Tm13 to the time Tm15. FIG. 6B is a diagram showing a time chart showing a time zone in which the defrosting operation for the outdoor heat exchanger 10b is performed. In FIG. 6B, it is assumed that the frost formation condition of the outdoor heat exchanger 10b is satisfied at the time Tm12, and the defrosting operation is performed from the time Tm13 to Tm16. Further, it is assumed that the start time of the defrosting operation for the total heat exchanger 40 is the time Tm14 after a certain time has elapsed from the time Tm12, but it has been advanced to the time Tm13 by the synchronous processing. When the defrosting operation for the total heat exchanger 40 is started at time Tm14, it is assumed that the defrosting operation for the total heat exchanger 40 is performed until time Tm17. During the time period from Tm13 to Tm15, when the defrosting operation for the outdoor heat exchanger 10b and the defrosting operation for the total heat exchanger 40 are performed at the same time, the amount of air blown per unit time of the exhaust fan 22g is not reduced. It is assumed that the amount of air required to defrost the total heat exchanger 40 is maintained.

As shown in FIG. 6, the time from the time Tm13 at which each defrosting operation for the total heat exchanger 40 and the outdoor heat exchanger 10b starts at the same time to the time Tm16 for ending the defrosting operation for the total heat exchanger 40. The amount of air supply is reduced in the band. If the defrosting operation for the total heat exchanger 40 and the defrosting operation for the outdoor heat exchanger 10b are started at the times t11 and t12 when the frost formation conditions are satisfied, the air is supplied in the time zone from the time Tm11 to Tm12, respectively. The amount was reduced. Further, if the defrosting operation for the outdoor heat exchanger 10b is not accelerated from the time Tm14 to Tm13, the amount of air supply is reduced not only in the time zone from time Tm13 to Tm16 but also in the time zone from time Tm16 to Tm17. Was there. As described above, in the first embodiment, the time zone in which the amount of air supply is reduced can be shortened.

FIG. 7 is a flowchart for explaining the synchronous processing of the defrosting operation performed in the first embodiment. In the following, the step is simply referred to as S. The process shown in FIG. 7 is called at regular time intervals by a main routine (not shown).

The integrated controller 30 determines whether or not the frost formation condition of the total heat exchanger 40 is satisfied in S101. When the frost formation condition of the total heat exchanger 40 is not satisfied (NO in S101), the integrated controller 30 returns the process to the main routine. When the frost formation condition of the total heat exchanger 40 is satisfied (YES in S101), the integrated controller 30 advances the process to S102. The integrated controller 30 determines in S102 whether or not the defrosting operation start time Ts1 of the total heat exchanger 40 has elapsed. The start time Ts1 is a time after a certain period of time has elapsed from the time when the frost formation condition of the total heat exchanger 40 is satisfied. The time interval between the time when the frosting condition is satisfied and the start time Ts1 can be appropriately determined by an actual machine experiment or simulation so that the lengthening of defrosting due to the progress of frosting is within the permissible range. Can be minutes. When the start time Ts1 has elapsed (YES in S102), the integrated controller 30 advances the process to S110. The integrated controller 30 returns the process to the main routine after performing the defrosting operation on the total heat exchanger 40 in S110. If the start time Ts1 has not elapsed (NO in S102), the integrated controller 30 advances the process to S103.

The integrated controller 30 determines whether or not the frost formation condition of the outdoor heat exchanger 10b is satisfied in S103. When the frost formation condition of the outdoor heat exchanger 10b is not satisfied (NO in S103), the integrated controller 30 returns the process to the main routine. When the frost formation condition of the outdoor heat exchanger 10b is satisfied (YES in S103), the integrated controller 30 advances the process to S104. The integrated controller 30 determines in S104 whether or not the defrosting operation start time Ts2 of the outdoor heat exchanger 10b has elapsed. The start time Ts2 is a time after a certain period of time has elapsed from the time when the frost formation condition of the outdoor heat exchanger 10b is satisfied. The time interval between the time when the frost formation condition is satisfied and the start time Ts2 can be appropriately determined by an actual machine experiment or simulation so that the lengthening of defrosting due to the progress of frost formation is within the permissible range. Can be minutes. When the start time Ts2 has elapsed (YES in S104), the integrated controller 30 advances the process to S120. The integrated controller 30 returns the process to the main routine after performing the defrosting operation on the outdoor heat exchanger 10b in S120. If the start time Ts2 has not elapsed (NO in S104), the integrated controller 30 advances the process to S105.

The integrated controller 30 determines in S105 whether the start time Ts1 is earlier than Ts2. When the start time Ts1 is earlier than Ts2 (YES in S105), the integrated controller 30 advances the process to S106. The integrated controller 30 waits until the start time Ts1 in S106, and then proceeds to the process in S130. When the start time Ts1 is after Ts2 (NO in S105), the integrated controller 30 advances the process to S107. The integrated controller 30 waits until the start time Ts2 in S107, and then proceeds to the process in S130. In S130, the integrated controller 30 performs a synchronous defrosting operation for simultaneously defrosting the total heat exchanger 40 and the outdoor heat exchanger 10b, and then returns the process to the main routine.

FIG. 8 is a flowchart for explaining the processing flow of S110 (defrosting operation for the total heat exchanger 40) of FIG. 7. As shown in FIG. 8, the integrated controller 30 stops the air supply fan 21g in S111 and advances the process to S112. The integrated controller 30 determines whether or not the rotation speed of the exhaust fan 22g is higher than the reference rotation speed in S112. When the rotation speed of the exhaust fan 22g is higher than the reference rotation speed (YES in S112), the integrated controller 30 advances the process to S114. When the rotation speed of the exhaust fan 22g is equal to or lower than the reference rotation speed (NO in S112), the integrated controller 30 sets the rotation speed of the exhaust fan 22g to a rotation speed higher than the reference rotation speed in S113 and proceeds to the process in S114. .. The reference rotation speed is a rotation speed that can secure an air flow amount equal to or more than a reference air flow amount sufficient for defrosting the total heat exchanger 40, and can be appropriately determined by an actual machine experiment or a simulation.

The integrated controller 30 determines whether or not the outdoor heat exchanger 10b is defrosted in S114. When the defrosting operation for the outdoor heat exchanger 10b is performed (YES in S114), the integrated controller 30 advances the process to S116. When the defrosting operation for the outdoor heat exchanger 10b is not performed (NO in S114), the compressor 10a is stopped in S115 and the process proceeds to S116.

After waiting for a certain period of time in S116, the integrated controller 30 advances the process to S117. Since the exhaust fan 22g is rotating at a rotation speed higher than the reference rotation speed, the high-temperature return air RA from the room passes through the total heat exchanger 40 while the integrated controller 30 is on standby in S116, and the total heat is generated. Melting of the frost generated on the exchanger 40 is promoted. The integrated controller 30 determines in S117 whether or not the exhaust temperature (temperature from the temperature sensor 1c) is larger than the reference temperature T1. The condition shown in S117 is the end condition of the defrosting operation for the total heat exchanger 40. When the exhaust temperature is equal to or lower than the reference temperature T1 (NO in S117), the integrated controller 30 returns the process to S111, assuming that the total heat exchanger 40 has not been sufficiently heated and the defrosting has not been completed. When the exhaust temperature is higher than the reference temperature T1 (YES in S117), the integrated controller 30 returns the process to S110 in FIG. 7, assuming that the total heat exchanger 40 is sufficiently heated and the defrosting is completed.

FIG. 9 is a flowchart for explaining the processing flow of S120 (defrosting operation for the outdoor heat exchanger 10b) of FIG. 7. As shown in FIG. 9, the integrated controller 30 controls the four-way valve 10d in step S121 to switch the circulation direction of the refrigerant in the opposite direction to the heating operation and proceed to the process in S122. The integrated controller 30 stops the air supply fan 21g in S122 and proceeds to the process in S123. The integrated controller 30 determines whether or not the total heat exchanger 40 is defrosted in S123. When the total heat exchanger 40 is defrosted (YES in S123), the integrated controller 30 advances the process to S125. When the defrosting operation for the total heat exchanger 40 is not performed (NO in S123), the integrated controller 30 stops the exhaust fan 22g in S124 and then proceeds to the process in S125. After waiting for a certain period of time in S125, the integrated controller 30 advances the process to S126. While the integrated controller 30 is on standby in S125, the refrigerant circulates in the refrigeration cycle to heat the outdoor heat exchanger 10b and promote the melting of the frost generated in the outdoor heat exchanger 10b.

The integrated controller 30 determines in S126 whether or not the piping temperature (temperature from the temperature sensor 10h or 10i) of the outdoor heat exchanger 10b is higher than the reference temperature T2. The condition shown in S126 is the end condition of the defrosting operation for the outdoor heat exchanger 10b. When the piping temperature of the outdoor heat exchanger 10b is equal to or lower than the reference temperature T2 (NO in S126), the integrated controller 30 determines that the outdoor heat exchanger 10b has not been sufficiently heated and defrosting has not been completed. The process is returned to S122. When the piping temperature of the outdoor heat exchanger 10b is higher than the reference temperature T2 (YES in S126), assuming that the outdoor heat exchanger 10b is sufficiently heated and defrosting is completed, the integrated controller 30 advances the process to S127. The integrated controller 30 controls the four-way valve 10d in S127 to switch the circulation direction of the refrigerant to the circulation direction of the heating operation, and returns the process to S120 in FIG.

FIG. 10 is a flowchart for explaining the processing flow of S130 (synchronous defrosting operation) of FIG. By controlling the four-way valve 10d in S131, the integrated controller 30 switches the circulation direction of the refrigerant in the opposite direction to the heating operation and advances the process to S132. The integrated controller 30 stops the air supply fan 21g in S132 and proceeds to the process in S133.

The integrated controller 30 determines whether or not the rotation speed of the exhaust fan 22g is higher than the reference rotation speed in S133. When the rotation speed of the exhaust fan 22g is higher than the reference rotation speed (YES in S133), the integrated controller 30 advances the process to S135. When the rotation speed of the exhaust fan 22g is equal to or lower than the reference rotation speed (NO in S133), the integrated controller 30 sets the rotation speed of the exhaust fan 22g to a rotation speed higher than the reference rotation speed in S134 and proceeds to the process in S135. ..

The integrated controller 30 waits for a certain period of time in S135, and then proceeds to process in S136. While the integrated controller 30 is on standby in S135, the refrigerant circulates in the refrigeration cycle to heat the outdoor heat exchanger 10b and promote the melting of the frost generated in the outdoor heat exchanger 10b. Further, since the exhaust fan 22 g is rotating at a rotation speed higher than the reference rotation speed, the high-temperature return air RA from the room passes through the total heat exchanger 40, and the frost generated in the total heat exchanger 40 is melted. It is promoted.

The integrated controller 30 determines in S136 whether or not the end condition of the defrosting operation for the total heat exchanger 40 is satisfied. When the termination condition of the defrosting operation for the total heat exchanger 40 is not satisfied (NO in S136), the integrated controller 30 returns the process to S135. When the end condition of the defrosting operation for the total heat exchanger 40 is satisfied (YES in S136), the integrated controller 30 advances the process to S137.

The integrated controller 30 determines in S137 whether or not the end condition of the defrosting operation for the outdoor heat exchanger 10b is satisfied. When the end condition of the defrosting operation for the outdoor heat exchanger 10b is not satisfied (NO in S137), the integrated controller 30 returns the process to S135. When the end condition of the defrosting operation for the outdoor heat exchanger 10b is satisfied (YES in S137), the integrated controller 30 switches the four-way valve in S138 and then returns the process to S130 in FIG. 7. The order of S136 and S137 may be reversed.

As described above, according to the ventilation device according to the first embodiment, the defrosting operation for the total heat exchanger and the defrosting operation for the heat exchanger functioning as the evaporator are synchronized to defrost the total heat exchanger. Extend the time period during which both operation and defrosting operation for the heat exchanger that was functioning as an evaporator are performed. As a result, the time zone in which the amount of air supply is reduced can be shortened, and the comfort of the user can be improved.

Further, in the first embodiment, the synchronous defrosting operation is performed until both the termination condition of the defrosting operation for the total heat exchanger and the termination condition for the heat exchanger functioning as the evaporator are satisfied. As a result, it is possible to prevent either the defrosting of the total heat exchanger or the defrosting of the heat exchanger functioning as the evaporator from being incomplete.

Embodiment 2.
The defrosting operation for the total heat exchanger is performed using the indoor air as a heat source. Therefore, the time required for the defrosting operation for the total heat exchanger may be longer than the time required for the defrosting operation for the outdoor heat exchanger as compared with the defrosting operation for the outdoor heat exchanger using the refrigeration cycle device as the heat source. There are many. In the synchronous defrosting operation according to the first embodiment, the defrosting of the outdoor heat exchanger is often completed earlier than the defrosting of the total heat exchanger. Therefore, in the second embodiment, when the defrosting of the outdoor heat exchanger is completed earlier than the defrosting of the total heat exchanger, the total heat exchanger is heated to accelerate the completion of defrosting. explain. By accelerating the completion of defrosting on the total heat exchanger, the time required for the synchronous defrosting operation can be shortened as compared with the first embodiment.

FIG. 11 is a functional block diagram showing the configuration of the ventilation device 200 according to the second embodiment. In FIG. 11, the outdoor unit is the same as in FIG. 1, and is not shown. In the ventilation unit 22 shown in FIG. 11, in the configuration of the ventilation unit 20 of FIG. 1, a ventilation fan 23g is added, and the ventilation controller 20f and the integrated controller 30 are replaced with the ventilation controller 22f and the integrated controller 32, respectively. .. As shown in FIG. 11, the blower fan 23g is arranged between the air supply fan 21g and the indoor heat exchanger 20b in the ventilation passage VF1. The rotation speed of the blower fan 23g is controlled by the ventilation controller 22f, and the blower fan 23g blows air from the ventilation hole VH2 to the ventilation hole VH1.

In the second embodiment, when the defrosting of the outdoor heat exchanger 10b is completed, first, a heating operation is performed to make the indoor heat exchanger 20b function as a condenser. The blower fan 23g is operated to blow the air heated by the indoor heat exchanger 20b to the total heat exchanger 40 to promote the melting of the frost generated in the total heat exchanger 40, and to the total heat exchanger 40. Accelerate the end of defrosting.

FIG. 12 is a flowchart for explaining the flow of the synchronous defrosting operation process according to the second embodiment. The process shown in FIG. 12 is a process performed in S130 of the process shown in FIG. 7.

As shown in FIG. 12, the integrated controller 32 controls the four-way valve 10d in S231 to switch the circulation direction of the refrigerant in the opposite direction to the heating operation and proceed to the process in S232. The integrated controller 32 stops the air supply fan 21g in S232 and advances the process to S233. The integrated controller 32 determines whether or not the rotation speed of the exhaust fan 22g is higher than the reference rotation speed in S233. When the rotation speed of the exhaust fan 22g is higher than the reference rotation speed (YES in S233), the integrated controller 32 advances the process to S235. When the rotation speed of the exhaust fan 22g is equal to or less than the reference rotation speed (NO in S233), the integrated controller 32 sets the rotation speed of the exhaust fan 22g to a rotation speed higher than the reference rotation speed in S234 and proceeds to the process in S235. ..

After waiting for a certain period of time in S235, the integrated controller 32 advances the process to S236. While the integrated controller 32 is on standby in S235, the refrigerant circulates in the refrigeration cycle to heat the outdoor heat exchanger 10b and promote the melting of the frost generated in the outdoor heat exchanger 10b. Further, since the exhaust fan 22 g is rotating at a rotation speed higher than the reference rotation speed, the high-temperature return air RA from the room passes through the total heat exchanger 40, and the frost generated in the total heat exchanger 40 is melted. It is promoted.

The integrated controller 32 determines in S236 whether or not the defrosting end condition for the outdoor heat exchanger 10b is satisfied. When the defrosting end condition for the outdoor heat exchanger 10b is not satisfied (NO in S236), the integrated controller 32 returns the process to S235. When the defrosting end condition for the outdoor heat exchanger 10b is satisfied (YES in S236), the integrated controller 32 returns the circulation direction of the refrigerant to that in the heating operation in S237 and proceeds to the process in S238. After S237 is performed, since the indoor heat exchanger 20b functions as a condenser, the air between the air supply fan 21g and the total heat exchanger 40 is heated by the indoor heat exchanger 20b.

The integrated controller 32 determines in S238 whether or not the end condition of the defrosting operation for the total heat exchanger 40 is satisfied. When the end condition of the defrosting operation for the total heat exchanger 40 is not satisfied (NO in S238), the integrated controller 32 advances the process to S239. The integrated controller 32 returns the process to S235 after operating the blower fan 23g in S239. By operating the blower fan 23g, the air heated by the indoor heat exchanger 20b is blown to the total heat exchanger 40. When the end condition of the defrosting operation for the total heat exchanger 40 is satisfied (YES in S238), the integrated controller 32 returns the process to the main routine after stopping the blower fan 23g in S240.

As described above, according to the ventilation device according to the second embodiment, the defrosting operation for the total heat exchanger and the defrosting operation for the heat exchanger functioning as the evaporator are synchronized as in the first embodiment. , Increase the time period during which both the defrosting operation for the total heat exchanger and the defrosting operation for the heat exchanger that was functioning as the evaporator are performed. As a result, the time zone in which the amount of air supply is reduced can be shortened, and the comfort of the user can be improved.

Further, in the second embodiment, in the synchronous defrosting operation, when the defrosting for the outdoor heat exchanger is completed earlier than the defrosting for the total heat exchanger, the heating operation is performed to perform the indoor heat in the ventilation unit. Make the exchanger function as a condenser. By blowing the air heated by the indoor heat exchanger to the total heat exchanger, the completion of defrosting on the total heat exchanger is accelerated. As a result, the time required for the synchronous defrosting operation can be shortened.

A modified example of the second embodiment.
In the second embodiment, when the defrosting of the outdoor heat exchanger is completed earlier than the defrosting operation of the total heat exchanger, the heating operation is performed and the air heated by the indoor heat exchanger in the ventilation unit is performed. The case where the total heat exchanger is heated to accelerate the completion of defrosting of the total heat exchanger by blowing air to the total heat exchanger has been described. The method for accelerating the termination of the total heat exchanger is not limited to the method described in the second embodiment. In the modified example of the second embodiment, a case where the return air from the room is heated by a heater to heat the total heat exchanger and accelerate the completion of defrosting will be described.

FIG. 13 is a functional block diagram showing the configuration of the ventilation device 200A according to the modified example of the second embodiment. In FIG. 13, the outdoor unit is the same as in FIG. 1, and is not shown. In the ventilation unit 221 shown in FIG. 13, in the configuration of the ventilation unit 20 of FIG. 1, the return air heater 51 is added, and the ventilation controller 20f and the integrated controller 30 are replaced with the ventilation controller 221f and the integrated controller 321 respectively. There is. As the return air heater 51, for example, a gas heater, an electric heater, and a heater that utilizes the heat of condensation from the indoor heat exchanger 20b can be used. As shown in FIG. 13, the return air heater 51 is installed near the ventilation hole VH3 in the ventilation passage VF2. The return air heater 51 heats the air between the ventilation holes VH3 and the total heat exchanger 40. The heating temperature of the return air heater 51 is controlled by the integrated controller 321 via the ventilation controller 221f.

FIG. 14 is a flowchart for explaining the flow of the synchronous defrosting operation process in the modified example of the second embodiment. The process shown in FIG. 14 is a process performed in S130 of the process shown in FIG. 7. The process shown in FIG. 14 is a process in which S239 and S240 in the process shown in FIG. 12 are replaced with S249 and S250, respectively.

As shown in FIG. 14, the integrated controller 321 switches the four-way valve 10d in S231, stops the air supply fan 21g in S232, and makes the rotation speed of the exhaust fan 22g higher than the reference rotation speed in S233 and S234. It is processed and waits for a certain period of time in S235. After that, when the end condition of the defrosting operation is satisfied (YES in S236), the integrated controller 32 returns the circulation direction of the refrigerant to that of the heating operation in S237, and proceeds to the process in S238.

The integrated controller 321 determines in S238 whether or not the end condition of the defrosting operation for the total heat exchanger 40 is satisfied. When the end condition of the defrosting operation for the total heat exchanger 40 is not satisfied (NO in S238), the integrated controller 321 advances the process to S249. After operating the return air heater 51 in S249, the integrated controller 321 returns the process to S235. By operating the return air heater 51, the air from the ventilation hole VH3 to the total heat exchanger 40 is heated. When the end condition of the defrosting operation for the total heat exchanger 40 is satisfied (YES in S238), the integrated controller 321 returns the process to the main routine after stopping the return air heater 51 in S250.

As described above, according to the ventilation device according to the modified example of the second embodiment, the time zone in which the air supply amount is reduced can be shortened as in the first embodiment. Furthermore, in the synchronous defrosting operation, when the defrosting of the heat exchanger functioning as the evaporator is completed earlier than the defrosting of the total heat exchanger, the total heat is heated by heating the return air from the room. The end of defrosting on the exchanger is accelerated. As a result, the time required for the synchronous defrosting operation can be shortened as in the second embodiment.

Embodiment 3.
In the first and second embodiments, there is a certain time interval between the establishment of the frost formation condition and the defrosting operation. Since frost formation progresses at the time interval, if the time interval is long, the defrosting operation performed thereafter becomes prominent, and the effect of synchronizing the defrosting operations may be lost. is there.

Therefore, in the third embodiment, the frost formation suppression operation is performed between the time when the frost formation condition is satisfied and the time when the frost removal operation is performed, so that the time interval from the establishment of the frost formation condition to the defrost operation Will be described with respect to the configuration which can be made longer than the first and second embodiments. Further, in the third embodiment, a process of shortening the time during which the frost formation suppression operation is performed to suppress an increase in power consumption due to the frost formation suppression operation will also be described.

FIG. 15 is a functional block diagram showing the configuration of the ventilation device 300 according to the third embodiment. In FIG. 15, the outdoor unit is the same as in FIG. 1, and is not shown. In the ventilation device 300 shown in FIG. 15, in the configuration of the ventilation device 100 shown in FIG. 1, the outside air heater 52 is added, and the ventilation controller 20f and the integrated controller 30 are replaced with the ventilation controller 23f and the integrated controller 33, respectively. Has been done. As the outside air heater 52, for example, a gas heater, an electric heater, and a heater that utilizes the heat of condensation from the indoor heat exchanger 20b can be used. As shown in FIG. 15, the outside air heater 52 is installed near the ventilation hole VH1 in the ventilation passage VF1. The outside air heater 52 heats the air between the ventilation holes VH1 and the total heat exchanger 40. The heating temperature of the outside air heater 52 is controlled by the integrated controller 33 via the ventilation controller 23f.

In the frost formation suppression operation for the total heat exchanger 40, the outside air OA from the ventilation hole VH1 is heated by the outside air heater 52, so that the cooling of the total heat exchanger 40 by the outside air OA is suppressed. As a result, frost formation on the total heat exchanger 40 is suppressed. The start condition of the frost formation suppression operation for the total heat exchanger 40 in the third embodiment is the frost formation condition of the total heat exchanger 40. The frosting condition of the total heat exchanger 40 in the third embodiment is that the outdoor air temperature is equal to or lower than the threshold temperature Tset1 (for example, −10 ° C.), and the temperature difference between the outdoor temperature and the indoor temperature is the threshold temperature difference ΔT1 (. For example, it is a condition that it is -35 deg) or less. The start condition of the frost formation suppression operation for the total heat exchanger 40 may be different from the frost formation condition of the total heat exchanger 40.

In the frost formation suppression operation for the outdoor heat exchanger 10b, the rotation speed of the outdoor fan 10g is increased. Heat exchange in the outdoor heat exchanger 10b is promoted, the evaporation temperature rises, and the sensible heat factor (SHF) rises. As a result, the temperature of the outdoor heat exchanger 10b rises, and frost formation on the outdoor heat exchanger 10b is suppressed. The start condition of the frost formation suppression operation for the outdoor heat exchanger 10b in the third embodiment is the frost formation condition of the outdoor heat exchanger 10b. The frost formation condition of the outdoor heat exchanger 10b in the third embodiment is that the outdoor air temperature is below the threshold temperature Tset2 (for example, 3 ° C.) and the piping temperature is below freezing. The start condition of the frost formation suppression operation for the outdoor heat exchanger 10b may be different from the frost formation condition for the outdoor heat exchanger 10b.

In the frost formation suppression operation for the total heat exchanger 40, the outside air heater 52 is operated. Further, in the frost formation suppression operation for the outdoor heat exchanger 10b, the rotation speed of the outdoor fan 10g is increased. As described above, in the frost formation suppression operation, processing that is not performed in the normal heating operation is performed. In the following, using FIGS. 16-18, the target heating capacity of the refrigeration cycle (the heating capacity required to achieve the target temperature by air conditioning) and the amount of heat recovered by the total heat exchanger are compared with those of normal heating operation. We will explain how it changes in the frost formation suppression operation.

FIG. 16 is a diagram showing a time chart of the power consumption when the frost formation suppression operation is not performed, the target heating capacity of the refrigeration cycle, and the amount of heat recovered by the total heat exchanger. 16 (a) to 16 (c) are diagrams showing time charts of power consumption, target heating capacity, and recovered heat amount, respectively. In FIGS. 16A to 16C, it is assumed that the normal heating operation is performed until the time Tm311 and the defrosting operation is performed until the time Tm311 to Tm312. During the defrosting operation, the air supply fan 21g is stopped, so that the power consumption is reduced. Since the defrosting operation is not intended for air conditioning, the target heating capacity during the defrosting operation is 0. During the defrosting operation, the air supply fan 21g is stopped and ventilation is not performed, so that the amount of heat recovered by the total heat exchanger 40 is zero. The power consumption, the target heating capacity, and the amount of recovered heat during the defrosting operation are the same as those in FIGS. 17 and 18 described below. As shown in FIGS. 16A to 16C, the power consumption, the target heating capacity, and the amount of recovered heat in the normal heating operation are the power W0, the heating capacity Q0, and the heat amount H0, respectively.

FIG. 17 is also a diagram showing a time chart of the power consumption when the frost formation suppression operation of the total heat exchanger 40 is performed, the target heating capacity of the refrigeration cycle, and the recovered heat amount of the total heat exchanger 40. 17 (a) to 17 (c) are diagrams showing time charts of power consumption, target heating capacity, and recovered heat amount, respectively. In FIGS. 17 (a) to 17 (c), it is assumed that the frost formation suppression operation is performed until the times Tm321 to Tm322 and the defrosting operation is performed until the times Tm322 to Tm323. As shown in FIG. 17A, in the frost formation suppression operation for the total heat exchanger 40, the outside air heater 52 is operated, so that the power consumption is higher than the power W0. As shown in FIG. 17B, since the outside air OA is heated by the outside air heater 52, the temperature of the supply air SA supplied to the room rises and approaches the target temperature. As a result, the target heating capacity is lower than the heating capacity Q0. As shown in FIG. 17C, since the temperature of the outside air OA is raised by the outside air heater 52, the temperature difference between the outside air OA and the return air RA, which exchange heat with the total heat exchanger 40, becomes small. As a result, the amount of heat recovered by the total heat exchanger 40 is smaller than the amount of heat H0.

FIG. 18 is also a diagram showing a time chart of the power consumption when the outdoor heat exchanger 10b is subjected to the frost formation suppression operation, the target heating capacity of the refrigeration cycle, and the amount of heat recovered by the total heat exchanger. 18 (a) to 18 (c) are diagrams showing time charts of power consumption, target heating capacity, and recovered heat amount, respectively. In FIGS. 18 (a) to 18 (c), it is assumed that the frost formation suppression operation is performed from time Tm331 to Tm332 and the defrost operation is performed from time Tm332 to Tm333. As shown in FIG. 18A, in the frost formation suppression operation for the outdoor heat exchanger 10b, since the outdoor fan 10g is operated, the power consumption is higher than the electric power W0. The operation of the outdoor fan 10 g arranged outdoors has almost no effect on the temperature of the outside air OA and the temperature of the return air RA. Therefore, as shown in FIGS. 18 (b) and 18 (c), the target heating capacity and the amount of recovered heat during the frost formation suppression operation for the outdoor heat exchanger 10b are almost the same as the heating capacity Q0 and the heat quantity H0, respectively. does not change.

As shown in FIGS. 17 (a) and 18 (a), the power consumption increases when the frost formation suppression operation is performed. From the viewpoint of suppressing power consumption, it is desirable that the time for performing the frost formation suppression operation is as short as possible.

In the third embodiment, the synchronous defrosting operation is performed as in the first and second embodiments. In the synchronous defrosting operation, the start time of either the defrosting operation for the total heat exchanger 40 or the defrosting operation for the outdoor heat exchanger 10b is advanced. When the start time is advanced, the time interval from the frost formation condition of the defrosting operation to the start time of the defrosting operation becomes short. Therefore, the amount of frost set up to the start time of the defrosting operation is reduced. As a result, the need to perform the frost formation suppression operation corresponding to the defrosting operation with the earlier start time is reduced.

Therefore, in the third embodiment, when the synchronous defrosting operation is performed, the case where the frost formation suppression operation corresponding to the defrosting operation with the earlier start time is satisfied than the normal start condition is limited. The frost formation suppression cooperation process to be performed when the start condition of is satisfied is performed. As a result, an increase in power consumption can be suppressed.

In the third embodiment, the outdoor temperature is the threshold temperature Tset1 (for example, the threshold temperature Tset1) as the start condition of the frost formation suppression operation for the total heat exchanger 40 when the defrosting operation for the total heat exchanger 40 is accelerated in the synchronous defrosting operation. The condition is that the temperature is -10 ° C. or less and the temperature difference between the outdoor temperature and the indoor temperature is the threshold temperature difference ΔT2 (for example, -50 deg) or less. Compared with the start condition of the frost suppression operation for the normal total heat exchanger 40, the start of the frost suppression operation for the total heat exchanger 40 when the defrost operation for the total heat exchanger 40 is accelerated in the synchronous defrost operation. Under the conditions, the temperature difference ΔT2 is smaller than the temperature difference ΔT1. Further, in the synchronous defrosting operation, the start condition of the frost formation suppression operation for the outdoor heat exchanger 10b when the defrosting operation for the outdoor heat exchanger 10b is accelerated is set so that the outdoor air temperature is below the threshold temperature Tset3 (for example, −10 ° C.). The condition is that the pipe temperature is below freezing. Comparing with the start conditions of the frost formation suppression operation for the normal outdoor heat exchanger 10b, the start of the frost formation suppression operation for the outdoor heat exchanger 10b when the defrost operation for the outdoor heat exchanger 10b is accelerated in the synchronous defrost operation. Under the conditions, the threshold temperature Tset3 is smaller than the threshold temperature Tset2.

FIG. 19 is a diagram showing a range of outside air temperatures in which a frost formation suppression operation is performed on the total heat exchanger 40. FIG. 19A is a diagram showing a range of temperature differences in which the frost formation suppression operation is performed when the start time of the defrost operation for the total heat exchanger 40 cannot be advanced in the synchronous defrost operation. FIG. 19B is a diagram showing a range of temperature differences in which the frost formation suppression operation is performed when the start time of the defrost operation for the total heat exchanger 40 is advanced in the synchronous defrost operation. In FIG. 19, it is assumed that, among the start conditions of the frost formation suppression operation for the total heat exchanger 40, the condition that the outdoor air temperature is equal to or lower than the threshold temperature Tset1 (for example, −10 ° C.) is satisfied.

As shown in FIG. 19A, when the start time of the defrosting operation cannot be advanced in the synchronous defrosting operation, the frost formation suppression operation is not performed when the temperature difference is larger than the threshold temperature difference ΔT1, and the temperature difference is the threshold. The frost formation suppression operation is performed when the temperature difference is ΔT1 or less. As shown in FIG. 19B, when the start time of the defrosting operation is advanced in the synchronous defrosting operation, the frost formation suppression operation is not performed when the temperature difference is larger than the threshold temperature difference ΔT2, and the temperature difference is the threshold temperature. When the difference is ΔT2 or less, the frost formation suppression operation is performed. When the start time of the defrosting operation is advanced, the frost formation suppression operation is not performed when the temperature difference is in the range of the threshold temperature difference ΔT2 to ΔT1. As a result, it is possible to suppress an increase in power consumption due to the frost formation suppression operation.

FIG. 20 is a diagram showing a temperature range between the outdoor temperature and the indoor temperature at which the frost formation suppression operation is performed on the outdoor heat exchanger 10b. FIG. 20A is a diagram showing a temperature range in which the frost formation suppression operation is performed when the start time of the defrost operation for the outdoor heat exchanger 10b cannot be advanced in the synchronous defrost operation. FIG. 20B is a diagram showing a temperature range in which the frost formation suppression operation is performed when the start time of the defrost operation for the outdoor heat exchanger 10b is advanced in the synchronous defrost operation. In FIG. 20, it is assumed that the condition that the pipe temperature is below the freezing point is satisfied among the start conditions of the frost formation suppression operation for the outdoor heat exchanger 10b.

As shown in FIG. 20A, when the start time of the defrosting operation cannot be advanced in the synchronous defrosting operation, the frost formation suppression operation is not performed when the outside air temperature is higher than the threshold temperature Tset2, and the outside air temperature is the threshold temperature. When the temperature is Tset2 or less, the frost formation suppression operation is performed. As shown in FIG. 20B, when the start time of the defrosting operation is advanced in the synchronous defrosting operation, the frost formation suppression operation is not performed when the outside air temperature is higher than the threshold temperature Tset3, and the outside air temperature is the threshold temperature Tset3. The frost formation suppression operation is performed when the following is true. When the start time of the defrosting operation is advanced, the frost formation suppression operation is not performed when the outside air temperature is in the range of the threshold temperature Tset3 to Tset2. As a result, it is possible to suppress an increase in power consumption due to the frost formation suppression operation.

FIG. 21 is a flowchart for explaining the flow of the frost formation suppression cooperation process in the third embodiment. The process shown in FIG. 21 is called at regular time intervals by a main routine (not shown). As shown in FIG. 21, the integrated controller 33 determines whether or not the frost formation condition of the total heat exchanger 40 is satisfied in S331. If the frost formation condition of the total heat exchanger 40 is not satisfied (NO in S331), the process proceeds to S332. The integrated controller 33 determines whether or not the frost formation condition of the outdoor heat exchanger 10b is satisfied in S332. When the frost formation condition of the outdoor heat exchanger 10b is not satisfied (NO in S332), the integrated controller 33 returns the process to the main routine. When the frost formation condition of the outdoor heat exchanger 10b is satisfied (YES in S332), the integrated controller 33 performs the frost formation suppression process of the outdoor heat exchanger 10b in S333, and then returns the process to the main routine.

When the frost formation condition of the total heat exchanger 40 is satisfied (YES in S331), the process proceeds to S334. The integrated controller 33 determines whether or not the frost formation condition of the outdoor heat exchanger 10b is satisfied in S334. When the frost formation condition of the outdoor heat exchanger 10b is not satisfied (NO in S334), the integrated controller 33 returns the process to the main routine after performing the frost formation suppression operation on the total heat exchanger 40 in S335. When the frost formation condition of the outdoor heat exchanger 10b is satisfied (YES in S334), the integrated controller 33 proceeds to S336.

In S336, the integrated controller 33 determines whether or not the start time Ts1 of the defrosting operation for the total heat exchanger 40 is earlier than the start time Ts2 for the defrosting operation for the outdoor heat exchanger 10b. When the start time Ts1 is earlier than the start time Ts2 (YES in S336), the integrated controller 33 performs the frost formation suppression operation on the total heat exchanger 40 in S337, and then proceeds to the process in S338. The integrated controller 33 determines in S338 whether or not the start condition of the frost formation suppression operation for the outdoor heat exchanger 10b is satisfied. The start condition is a condition that is more limited than the frost formation condition of the outdoor heat exchanger 10b. If the start condition is not satisfied (NO in S338), the integrated controller 33 returns the process to the main routine. When the start condition is satisfied (YES in S338), the integrated controller 33 returns the process to the main routine after performing the frost formation suppression operation on the outdoor heat exchanger 10b in S339.

When the start time Ts1 is after the start time Ts2 (NO in S336), the integrated controller 33 performs the frost formation suppression operation on the outdoor heat exchanger 10b in S340, and then proceeds to the process in S341. The integrated controller 33 determines in S341 whether or not the start condition of the frost formation suppression operation for the total heat exchanger 40 is satisfied. The start condition is a condition that is more limited than the frost formation condition of the total heat exchanger 40. If the start condition is not satisfied (NO in S341), the integrated controller 33 returns the process to the main routine. When the start condition is satisfied (YES in S341), the integrated controller 33 returns the process to the main routine after performing the frost formation suppression operation on the total heat exchanger 40 in S342.

FIG. 22 is a flowchart for explaining the flow of the frost formation suppression operation process (S335, S337, and S342 in FIG. 21) for the total heat exchanger 40. As shown in FIG. 22, the integrated controller 33 operates the outside air heater 52 in S311 and advances the process to S312. After waiting for a certain period of time in S312, the integrated controller 33 advances the process to S313. In S313, the integrated controller determines whether or not the start time Ts1 of the defrosting operation for the total heat exchanger has elapsed. If the start time Ts1 has not elapsed (NO in S313), the process is returned to SS312. If the start time Ts1 has elapsed (YES in S313), the process proceeds to S314. After stopping the outside air heater 52 in S314, the integrated controller 33 returns the process to S335, S337, or S342 in FIG.

FIG. 23 is a flowchart for explaining the flow of the frost formation suppression operation process (S333, S340, and S339 in FIG. 21) for the outdoor heat exchanger 10b. As shown in FIG. 23, the integrated controller 33 increases the rotation speed of the outdoor fan 10 g in S321 to increase the amount of air blown per unit time, and then proceeds to the process in S322. After waiting for a certain period of time in S322, the integrated controller 33 advances the process to S323. The integrated controller 33 determines in S323 whether or not the defrosting start time of the outdoor heat exchanger 10b has elapsed. If the defrosting start time of the outdoor heat exchanger 10b has not passed (NO in S323), the integrated controller 33 returns the process to S322. When the defrosting start time of the outdoor heat exchanger 10b has elapsed (YES in S323), the integrated controller 33 advances the process to S324. The integrated controller 33 stops the outdoor fan 10g in S324 and returns the process to S333, S340, or S339 in FIG.

As described above, according to the ventilation device according to the third embodiment, the defrosting operation for the total heat exchanger and the defrosting operation for the heat exchanger functioning as the evaporator are synchronized as in the first embodiment. , Increase the time period during which both the defrosting operation for the total heat exchanger and the defrosting operation for the heat exchanger that was functioning as the evaporator are performed. As a result, the time zone in which the amount of air supply is reduced can be shortened, and the comfort of the user can be improved.

Further, in the third embodiment, the frost formation suppression operation is performed between the time when the frost formation condition is satisfied and the time when the defrost operation is performed, so that the time interval from the establishment of the frost formation condition to the defrost operation is performed. Can be longer than embodiments 1 and 2. In addition, the power consumption of the frost suppression operation is performed by performing the frost suppression cooperation process that limits the start conditions of the frost suppression operation corresponding to the defrost operation whose start time is earlier in the synchronous defrost operation. Can be suppressed from increasing.

Embodiment 4.
In the first to third embodiments, the case where the total heat exchanger is a static total heat exchanger as shown in FIG. 4 has been described. The total heat exchanger is not limited to the static total heat exchanger. In the fourth embodiment, a case where the total heat exchanger is a rotary total heat exchanger will be described.

FIG. 24 is a functional block diagram showing the configuration of the ventilation device 400 according to the fourth embodiment. In FIG. 24, the outdoor unit is the same as in FIG. 1, and is not shown. In the ventilation unit 24 shown in FIG. 24, in the configuration of the ventilation unit 20 of FIG. 1, the total heat exchanger 40, the ventilation controller 20f, and the integrated controller 30 are the total heat exchanger 41, the ventilation controller 24f, and the integrated controller 34. Have been replaced by, respectively.

As shown in FIG. 24, the total enthalpy heat exchanger 44 includes a heat transferable and hygroscopic rotor member and a motor (not shown) for rotating the rotor member. The rotor member is formed with a plurality of holes for allowing air to pass in a certain ventilation direction. The rotor member covers the ventilation passages VF1 and VF2. The rotor member has a disk shape and is arranged so that its center is located on the boundary between the ventilation passages VF1 and VF2. The rotor member rotates about an axis that passes through the center and is parallel to the ventilation direction. The rotation speed of the motor is controlled by the integrated controller 34 via the ventilation controller 24f.

When the return air RA from the ventilation hole VH3 passes through the total heat exchanger 44, total heat is accumulated in the rotor member. When the rotor member rotates, the portion of the rotor member in which the total heat is accumulated enters the ventilation passage VF1. When the outside air OA from the ventilation hole VH1 passes through the portion, the accumulated total heat is absorbed by the outside air OA. Like the stationary total heat exchanger, the rotary total heat exchanger 44 not only ventilates but also recovers the total heat contained in the return air RA and supplies the total heat to the outside air OA. It has the function of returning to the room.

The synchronous defrosting operation for the fourth embodiment, the defrosting operation for the total heat exchanger 44, the defrosting operation for the outdoor heat exchanger 10b, the frost formation suppression cooperative processing, and the frost formation suppression operation for the outdoor heat exchanger 10b, respectively. This is the same as in FIGS. 7 to 9, 21 and 23. In the frost formation suppression operation for the total heat exchanger 44 in the fourth embodiment, the rotation speed of the total heat exchanger 44 is reduced. Since the total heat exchanger 44 continuously contacts the high-temperature return air RA for a long time, frost formation on the total heat exchanger 44 is suppressed. The start condition of the frost formation suppression operation for the total heat exchanger 44 in the fourth embodiment is the frost formation condition of the total heat exchanger 44 as in the third embodiment. Similar to the third embodiment, the start condition of the frost formation suppression operation for the total heat exchanger 44 may be different from the frost formation condition of the total heat exchanger 44.

FIG. 25 is a flowchart for explaining the defrost suppression process for the total heat exchanger 44. The integrated controller 34 reduces the rotation speed of the total heat exchanger 44 in S401 and advances the process to S402. After waiting for a certain period of time in S402, the integrated controller 34 advances the process to S403. The integrated controller 34 determines in S403 whether or not the defrosting start time of the total heat exchanger 44 has elapsed. If the defrosting start time of the total heat exchanger 44 has not elapsed (NO in S403), the integrated controller 34 returns the process to S402. If the defrosting start time of the total heat exchanger 44 has elapsed (YES in S403), the integrated controller 34 returns the process to S335, S337, or S342 of FIG.

FIG. 26 is also a diagram showing a time chart of the power consumption when the frost formation suppression operation is performed on the total heat exchanger 44, the target heating capacity of the refrigeration cycle, and the recovered heat amount of the total heat exchanger 44. 26 (a) to 26 (c) are diagrams showing time charts of power consumption, target heating capacity, and recovered heat amount, respectively. In FIGS. 26A to 26C, it is assumed that the frost formation suppression operation is performed from time Tm401 to Tm402 and the defrosting operation is performed from time Tm402 to Tm403. As shown in FIG. 26 (c), in the frost formation suppression operation for the total heat exchanger 44, the amount of heat recovered by the total heat exchanger 44 is larger than the amount of heat H0 in order to reduce the rotation speed of the total heat exchanger 44. It becomes smaller. Since the target heating capacity of the refrigeration cycle is increased, the heating capacity of the refrigeration cycle is increased. As a result, the power consumption is higher than the power W0. Also in the fourth embodiment, the increase in power consumption is suppressed by limiting the start conditions of the frost formation suppression operation for the total heat exchanger 44 as in the third embodiment.

As described above, the ventilation device according to the fourth embodiment can also shorten the time zone in which the amount of air supply is reduced and improve the comfort of the user, as in the first embodiment. Further, also in the fourth embodiment, similarly to the third embodiment, the time interval from the establishment of the frost formation condition to the defrosting operation can be made longer than in the first and second embodiments, and the frost formation can be performed. It is possible to suppress an increase in power consumption due to the suppressed operation.

It is also planned that the embodiments disclosed this time will be appropriately combined and implemented within a consistent range. It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

1a, 1b, 1c, 10h, 10i, 10j, 20h, 20i Temperature sensor, 10 outdoor unit, 10a compressor, 10b outdoor heat exchanger, 10d four-way valve, 10e accumulator, 10f outdoor controller, 10g outdoor fan, 10k, 10m Pressure sensor, 20, 22, 24, 221 ventilation unit, 20b indoor heat exchanger, 20c expansion valve, 20f, 22f, 23f, 24f, 221f ventilation controller, 21g air supply fan, 22g exhaust fan, 23g blower fan, 30, 32, 33, 34, 321 integrated controller, 40, 40A, 40B, 41, 44 total heat exchanger, 41A, 41B seat member, 42A, 42B flow path forming member, 51 return air heater, 52 outside air heater, 100, 200 , 300,400 Ventilation system, VF1, VF2 ventilation passages, VH1, VH2, VH3, VH4 ventilation holes.

Claims (2)

A ventilation device that outputs air from the first ventilation hole from the second ventilation hole and outputs air from the third ventilation hole from the fourth ventilation hole.
A first ventilation path connecting the first ventilation hole and the second ventilation hole,
A first ventilation device that blows air from the first ventilation hole to the second ventilation hole in the first ventilation passage.
A second ventilation path connecting the third ventilation hole and the fourth ventilation hole,
A second ventilation device that blows air from the third ventilation hole to the fourth ventilation hole in the second ventilation passage.
The air that is arranged between the first ventilation hole and the second ventilation hole and is arranged between the third ventilation hole and the fourth ventilation hole and passes through the first ventilation passage and the first ventilation hole. The first heat exchanger, which exchanges sensible heat and latent heat with the air passing through the two ventilation passages,
First, the refrigerant includes the second heat exchanger, the compressor, the third heat exchanger, and the expansion valve, and the refrigerant is the second heat exchanger, the compressor, the third heat exchanger, and the expansion valve in this order. A refrigeration cycle device that circulates in the circulation direction,
A control device for performing a defrosting operation for each of the first heat exchanger and the second heat exchanger is provided.
The refrigeration cycle device further includes a flow path switching device that switches the direction in which the refrigerant circulates to the first circulation direction or the second circulation direction opposite to the first circulation direction.
The third heat exchanger exchanges heat between the air between the first heat exchanger and the second ventilation hole and the refrigerant.
The control device performs a first defrosting operation on the first heat exchanger after the first frosting condition is satisfied, and a second defrosting operation on the second heat exchanger after the second frosting condition is satisfied. If the second frost condition is satisfied after the first frost condition is satisfied and before the first defrost operation is performed, the first heat exchanger and the second heat exchanger are satisfied. When the first defrosting condition is satisfied after the second defrosting condition is satisfied and before the second defrosting operation is performed after performing the third defrosting operation for defrosting both of the above. 3 Defrost operation,
In the first defrosting operation, the control device reduces the amount of air blown per unit time of the first blowing device, and in the second defrosting operation, controls the flow path switching device to circulate the refrigerant. The direction is switched from the first circulation direction to the second circulation direction, and the amount of air blown per unit time of each of the first blower device and the second blower device is reduced. In the third defrosting operation, the flow By controlling the path switching device to switch the circulation direction of the refrigerant from the first circulation direction to the second circulation direction, the amount of air blown per unit time of the first blower device is reduced, and the unit of the second blower device. A ventilation device that makes the amount of air blown per hour equal to or greater than the standard amount of air blown. This is a defrost control method performed in a ventilation device that outputs air from the first ventilation hole from the second ventilation hole and outputs air from the third ventilation hole from the fourth ventilation hole.
The ventilation device is
A first ventilation path connecting the first ventilation hole and the second ventilation hole,
A first ventilation device that blows air from the first ventilation hole to the second ventilation hole in the first ventilation passage.
A second ventilation path connecting the third ventilation hole and the fourth ventilation hole,
A second blower that blows air from the third vent to the fourth vent in the second vent.
The air that is arranged between the first ventilation hole and the second ventilation hole and is arranged between the third ventilation hole and the fourth ventilation hole and passes through the first ventilation passage and the first ventilation hole. The first heat exchanger, which exchanges sensible heat and latent heat with the air passing through the two ventilation passages,
First, the refrigerant includes the second heat exchanger, the compressor, the third heat exchanger, and the expansion valve, and the refrigerant is the second heat exchanger, the compressor, the third heat exchanger, and the expansion valve in this order. A refrigeration cycle device that circulates in the circulation direction,
A control device for performing a defrosting operation for each of the first heat exchanger and the second heat exchanger is provided.
The refrigeration cycle device further includes a flow path switching device that switches the direction in which the refrigerant circulates to the first circulation direction or the second circulation direction opposite to the first circulation direction.
The third heat exchanger exchanges heat between the air between the first heat exchanger and the second ventilation hole and the refrigerant.
The defrost control method is
The step of performing the first defrosting operation on the first heat exchanger after the first frosting condition is satisfied, and
A step of performing a second defrosting operation on the second heat exchanger after the second frosting condition is satisfied, and
If the second frost condition is satisfied after the first frost condition is satisfied and before the first defrost operation is performed, both the first heat exchanger and the second heat exchanger are used. Steps to perform the third defrosting operation to defrost,
If the first frost condition is satisfied after the second frost condition is satisfied and before the second frost operation is performed, the step of performing the third frost operation is included.
The step of performing the first defrosting operation includes a step of reducing the amount of air blown per unit time of the first blower device.
The step of performing the second defrosting operation includes a step of controlling the flow path switching device to switch the circulation direction of the refrigerant from the first circulation direction to the second circulation direction, the first blower device, and the first. 2 Including the step of reducing the amount of air blown per unit time of each blower.
The step of performing the third defrosting operation includes a step of controlling the flow path switching device to switch the circulation direction of the refrigerant from the first circulation direction to the second circulation direction and a unit time of the first blower. A defrost control method including a step of reducing the amount of air blown per unit and a step of setting the amount of air blown per unit time of the second blower device to be equal to or greater than the reference air amount.

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