JP7013990B2 - Vehicle air conditioner - Google Patents

Description

The disclosure in this specification relates to a vehicle air conditioner.

Patent Document 1 discloses a seat air conditioner in which a compact air conditioner unit can be attached to the lower part of a seat in a vehicle. The seat air conditioner includes a groove for storing condensed water generated on the surface of the evaporator and an ultrasonic generator for evaporating the condensed water collected in the groove.

Japanese Unexamined Patent Publication No. 2016-14015

In the configuration of the prior art, the condensed water generated by the evaporator is evaporated by using an ultrasonic generator, a heater, or the like. Alternatively, a porous body is used to bring the condensed water generated in the evaporator into contact with the condenser to evaporate it. For this reason, it is necessary to treat the generated condensed water by providing a gutter that guides the condensed water to a predetermined position, a device that evaporates the condensed water, and the like. Further improvements are required for vehicle air conditioners in the above-mentioned viewpoints or in other viewpoints not mentioned.

One object disclosed is to provide a vehicle air conditioner capable of treating condensed water using the heat of a refrigerant.

The vehicle air conditioner disclosed herein includes a refrigeration cycle device (10) having a compressor (11), a first heat exchanger (31), a second heat exchanger (41), and a decompression device (12). , The air conditioner case (51) that houses the first heat exchanger and the second heat exchanger inside, the first heat exchanger functions as a condenser, and the second heat exchanger functions as an evaporator. A refrigerant switching device (25, 325) that switches between the first refrigerant mode and the second refrigerant mode in which the first heat exchanger functions as an evaporator and the second heat exchanger functions as a condenser, and the inside of the air conditioning case. A blower (32, 42, 232) that allows air to flow into the vehicle, an indoor communication port (61, 237, 247) that is installed in the air conditioner case and allows air to flow into the vehicle interior, and an indoor communication port (61, 237, 247) that is installed in the air conditioner case to the outside of the vehicle interior. The outdoor communication port (33, 43, 233, 243) through which the air to be sent out flows, the first ventilation mode in which the air passing through the first heat exchanger is flowed to the indoor communication port, and the air passing through the second heat exchanger are indoors. A blower switching device (35, 45, 235, 245) that switches between the second blower mode that flows through the communication port, and a water detection device that detects the condensed water generated in the first heat exchanger or the second heat exchanger (35, 45, 235, 245). 39, 49, 238, 248, 271) and when the amount of condensed water detected by the water detection device exceeds a predetermined amount, the refrigerant switching device is controlled to switch between the first refrigerant mode and the second refrigerant mode. It is provided with a control device (90) for switching between the first blast mode and the second blast mode by controlling the blast switching device while switching.

According to the disclosed vehicle air conditioner, when the amount of condensed water detected by the water detection device exceeds a predetermined amount, the refrigerant switching device is controlled to switch between the first refrigerant mode and the second refrigerant mode. , The blower switching device is controlled to switch between the first blower mode and the second blower mode. Therefore, the condensed water generated on the surface of the heat exchanger, which has functioned as an evaporator, can be evaporated by using the heat of the refrigerant and processed, and the air conditioning operation can be performed even during the processing of the condensed water. ..

The disclosed embodiments herein employ different technical means to achieve their respective objectives. The claims and the reference numerals in parentheses described in this section exemplify the correspondence with the parts of the embodiments described later, and are not intended to limit the technical scope. The objectives, features, and effects disclosed herein will be further clarified by reference to the subsequent detailed description and accompanying drawings.

It is external perspective view of the vehicle equipped with the air conditioner for a vehicle. It is a top view which shows the structure of the air conditioner for a vehicle. It is a side view which shows the structure of the air conditioner for a vehicle. It is a block diagram which shows the control system of the air conditioner for a vehicle. It is a top view which shows the structure of the air conditioner for a vehicle in the cooling operation which used the 2nd heat exchanger as an evaporator. It is a top view which shows the structure of the air conditioner for a vehicle in the cooling operation which used the 1st heat exchanger as an evaporator. It is a top view which shows the structure of the air conditioner for vehicles in 2nd Embodiment. It is a top view which shows the structure of the air conditioner for a vehicle in the cooling operation which used the 2nd heat exchanger as an evaporator in 2nd Embodiment. It is a top view which shows the structure of the air conditioner for a vehicle in the cooling operation which used the 1st heat exchanger as an evaporator in 2nd Embodiment. It is a top view which shows the structure of the air conditioner for a vehicle in the 1st refrigerant mode which used the 2nd heat exchanger as an evaporator in 3rd Embodiment. It is a top view which shows the structure of the air conditioner for a vehicle in the 2nd refrigerant mode which used the 1st heat exchanger as an evaporator in 3rd Embodiment.

A plurality of embodiments will be described with reference to the drawings. In a plurality of embodiments, functionally and / or structurally corresponding parts and / or related parts may be designated with the same reference code or reference numerals having different hundreds or more digits. References can be made to the description of other embodiments for the corresponding and / or associated parts.

1st Embodiment In FIG. 1, the vehicle air conditioner 1 is mounted on a vehicle 5. The vehicle air conditioner 1 is a device that adjusts the temperature of the air taken into the vehicle air conditioner 1 and blows it out into the vehicle interior. In other words, the vehicle air conditioner 1 is a device that performs air conditioning operations such as heating operation, cooling operation, and dehumidifying operation in the vehicle interior. The vehicle air conditioner 1 is arranged under the seat 2. The vehicle air conditioner 1 can be used as a seat air conditioner that performs air conditioning operation for an occupant sitting in the seat 2. However, the installation position of the vehicle air conditioner 1 is not limited to under the seat 2, and can be installed at any position of the vehicle 5.

In FIG. 2, the vehicle air conditioner 1 includes a compressor 11, a first heat exchanger 31, a decompression device 12, and a second heat exchanger 41. The vehicle air conditioner 1 includes a refrigerant pipe 20 that connects the compressor 11, the first heat exchanger 31, the decompression device 12, and the second heat exchanger 41. The refrigerant pipe 20 includes a four-way valve 25 that switches the refrigerant flow path. The four-way valve 25 provides a refrigerant switching device that switches the flow path of the refrigerant. The vehicle air conditioner 1 is a refrigerating cycle device 10 that heats and cools the surrounding air by utilizing a state change such as condensation and evaporation of a refrigerant.

The compressor 11 is a device that compresses a gaseous refrigerant into a high temperature and high pressure state. The depressurizing device 12 is a device that lowers the pressure of the refrigerant to facilitate evaporation from a liquid to a gas. As the depressurizing device 12, various types of devices such as a valve device such as an expansion valve whose throttle amount can be changed and a piping device having a fixed throttle amount such as a capillary tube can be adopted.

The first heat exchanger 31 and the second heat exchanger 41 are devices that function as an evaporator or a condenser. The first heat exchanger 31 and the second heat exchanger 41 are devices that exchange heat between the surrounding air and the refrigerant flowing inside. The condenser is a device that condenses a gaseous refrigerant compressed by the compressor 11 into a liquid. The condenser is a heat exchanger that dissipates the heat of the refrigerant to the surroundings in the process of condensing the refrigerant to heat the air around the condenser. The evaporator is a device that evaporates the liquid refrigerant decompressed by the decompression device 12 into a gas. The evaporator is a heat exchanger that cools the air around the evaporator by taking heat of vaporization from the surrounding air in the process of evaporating the refrigerant.

The vehicle air conditioner 1 includes a first blower 32 and a second blower 42. The first blower 32 and the second blower 42 are devices for transporting a fluid such as air by rotating a fan. The first blower 32 and the second blower 42 are centrifugal blowers that discharge air sucked from a central portion provided with a rotating shaft in a direction away from the central portion. The first blower 32 is provided directly above the central portion of the first heat exchanger 31. The second blower 42 is provided directly above the central portion of the second heat exchanger 41.

The vehicle air conditioner 1 includes a metal air conditioner case 51. However, the material forming the air conditioning case 51 is not limited to metal, and resin or the like may be used. The air conditioning case 51 includes a compressor 11, a first heat exchanger 31, a decompression device 12, a second heat exchanger 41, a first blower 32, and a second blower 42 inside. However, it is not necessary to store all the parts constituting the refrigerating cycle device 10 inside the air conditioning case 51. For example, the compressor 11 and the decompression device 12 may be arranged outside the air conditioning case 51. In other words, parts having a small contribution to heating and cooling of air may be arranged outside the air conditioning case 51.

The vehicle air conditioner 1 includes a duct 60. The duct 60 communicates with two blowers, a first blower 32 and a second blower 42. The duct 60 includes an indoor communication port 61. The indoor communication port 61 communicates with the inside of the vehicle 5. The indoor communication port 61 is an opening for sending conditioned air into the vehicle interior. The duct 60 includes a first outdoor communication port 33 and a second outdoor communication port 43. The first outdoor communication port 33 and the second outdoor communication port 43 communicate with the outside of the vehicle 5. The first outdoor communication port 33 and the second outdoor communication port 43 are openings for sending the exhaust heat generated by the refrigerating cycle device 10 to the outside of the vehicle interior. During the cooling operation, the conditioned air cooled by the evaporator is flowed through the indoor communication port 61, and the air heated by the condenser is flowed through the first outdoor communication port 33 or the second outdoor communication port 43. On the other hand, during the heating operation, the conditioned air heated by the condenser is flowed through the indoor communication port 61, and the air cooled by the evaporator is flowed through the first outdoor communication port 33 or the second outdoor communication port 43.

Inside the duct 60, a first interior door 35 and a first outdoor door 36 are provided. The first interior door 35 and the first outdoor door 36 are devices for switching the flow path of air flowing through the duct 60. The first interior door 35 is provided between the first blower 32 and the indoor communication port 61. When the first interior door 35 is open, the wind sent from the first blower 32 flows into the vehicle interior. The first outdoor door 36 is provided between the first blower 32 and the first outdoor communication port 33. When the first outdoor door 36 is open, the wind sent from the first blower 32 flows out of the vehicle interior. The first interior door 35 provides a blower switching device.

Inside the duct 60, a second interior door 45 and a second outdoor door 46 are provided. The second interior door 45 and the second outdoor door 46 are devices for switching the flow path of air flowing through the duct 60. The second interior door 45 is provided between the second blower 42 and the indoor communication port 61. When the second interior door 45 is open, the wind sent from the second blower 42 flows into the vehicle interior. The second outdoor door 46 is provided between the second blower 42 and the second outdoor communication port 43. When the second outdoor door 46 is open, the wind sent from the second blower 42 flows out of the vehicle interior. The second interior door 45 provides a blower switching device.

The first interior door 35, the first outdoor door 36, the second interior door 45, and the second outdoor door 46 are plate doors whose lid portions rotate around a rotation axis to adjust the opening degree. However, the door method is not limited to the plate door, and various types of doors such as film doors and rotary doors can be adopted. Further, the first interior door 35 and the second interior door 45 may be provided by one door. That is, a state in which a rotary door is arranged between the indoor communication port 61, the first heat exchanger 31 and the second heat exchanger 41, and the indoor communication port 61 and the first heat exchanger 31 are communicated with each other. The state in which the indoor communication port 61 and the second heat exchanger 41 are communicated with each other may be switched.

In FIG. 3, the indoor communication port 61 is located between the first blower 32 and the second blower 42. The wind blown from the indoor communication port 61 is directly blown to the occupant seated in the seat 2. Here, a ventilation passage may be provided inside the seat 2 so that the air conditioner is blown out from the back side of the occupant or the like. The first blower 32 sucks in air from the lower side in the direction of gravity, which is the side on which the first heat exchanger 31 is located, and discharges it into the duct 60. Since the first blower 32 and the first heat exchanger 31 are adjacent to each other with almost no gap, the first blower 32 passes through the first heat exchanger 31 and sucks in a large amount of heat exchanged air. In other words, the configuration is such that the air that has not passed through the first heat exchanger 31 and has not exchanged heat is hardly sucked.

The second blower 42 sucks in air from the lower side in the direction of gravity, which is the side on which the second heat exchanger 41 is located, and discharges it into the duct 60. Since the second blower 42 and the second heat exchanger 41 are adjacent to each other with almost no gap, the second blower 42 passes through the second heat exchanger 41 and sucks in a large amount of heat exchanged air. In other words, the configuration is such that the air that has not passed through the second heat exchanger 41 and has not exchanged heat is hardly sucked.

The lid portions of the first interior door 35 and the first outdoor door 36 rotate in a direction away from the first blower 32. Therefore, when the inside of the duct 60 becomes abnormally high pressure due to the drive of the first blower 32, the first indoor door 35 and the first outdoor door 36 are pushed by the wind to open, resulting in an abnormally high pressure state. It can be prevented from continuing. Further, even when a strong wind is received from the outside of the duct 60 in the closed first outdoor door 36, the force is applied in the direction in which the lid portion is closed, so that the first outdoor door 36 is unintentionally opened. It can be suppressed from being stored. Therefore, it is possible to prevent foreign matter from entering the inside of the air conditioning case 51 due to the wind from the outside.

The lids of the second interior door 45 and the second outdoor door 46 also rotate in the direction away from the second blower 42. Therefore, similarly to the first indoor door 35 and the first outdoor door 36, it is possible to obtain the effect of suppressing an abnormally high pressure state inside the duct 60 and the effect of suppressing the intrusion of foreign matter from the outside.

A first water sensor 39 is provided below the first heat exchanger 31. The first water sensor 39 is a sensor that detects the amount of water present on the surface of the first heat exchanger 31. The first water sensor 39 detects the amount of condensed water generated by the dew condensation of moisture in the air when, for example, the first heat exchanger 31 is used as an evaporator. The first water sensor 39 only needs to be able to detect the amount of water, and various detection methods can be adopted. For example, an electric sensor that detects the change in electrical resistance due to water, an optical sensor that detects the state of the surface of the first heat exchanger 31 with light, a weight sensor that detects the weight of water, and the like are adopted. It is possible. Further, the installation position of the first water sensor 39 can be appropriately changed depending on the water detection method. The second heat exchanger 41 is also provided with a second water sensor 49 similar to the first water sensor 39. The first water sensor 39 and the second water sensor 49 provide a water detection device.

FIG. 4 shows a control system of the vehicle air conditioner 1. In the control system, the control device (ECU) 90 is an electronic control unit (Electronic Control Unit). The control device 90 is provided by a microcomputer having a storage medium readable by a computer. The storage medium is a non-transitional substantive storage medium that stores a computer-readable program non-temporarily. The storage medium may be provided by a semiconductor memory, a magnetic disk, or the like. The control device 90 may be provided by one computer, or a set of computer resources linked by a data communication device. By being executed by the controller 90, the program causes the controller 90 to function as the controller 90 described herein and to perform the methods described herein. ..

The means and / or functions provided by the control system can be provided by the software recorded in the substantive memory device and the computer, software only, hardware only, or a combination thereof running the software. For example, if the control device 90 is provided by an electronic circuit that is hardware, it can be provided by a digital circuit including a large number of logic circuits, or an analog circuit.

The control system has a plurality of signal sources as input devices that supply signals indicating information input to the control device 90. The control system acquires information by storing the information in the memory device by the control device 90. The control system has a plurality of controlled objects whose behavior is controlled by the control device 90 as an output device. The control system controls the behavior of the controlled object by converting the information stored in the memory device into a signal and supplying it to the controlled object.

The control device 90, the signal source, and the controlled object included in the control system provide various elements. At least some of those elements can be called blocks for performing functions. From another point of view, at least some of those elements can be referred to as modules or sections that are interpreted as a configuration. Further, the elements included in the control system can be called the means for realizing the function only intentionally.

The control device 90 is connected to the room temperature sensor 91. The room temperature sensor 91 is a sensor that measures the temperature inside the vehicle interior. The vehicle air conditioner 1 performs air conditioning control so that the temperature measured by the room temperature sensor 91 approaches the set target temperature. In other words, if the temperature inside the vehicle interior is higher than the target temperature, the cooling operation is performed, and if the temperature inside the vehicle interior is lower than the target temperature, the heating operation is performed.

The control device 90 is connected to the first water sensor 39 and the second water sensor 49. The control device 90 acquires information on the amount of condensed water generated on the surface of the first heat exchanger 31 from the first water sensor 39. Further, the control device 90 acquires information on the amount of condensed water generated on the surface of the second heat exchanger 41 from the second water sensor 49. The information on the amount of condensed water is information that can grasp how much condensed water is generated, such as information on the weight of the generated condensed water and information on whether or not the amount exceeds a preset predetermined amount. Just do it. However, the amount of condensed water in the entire heat exchanger may be estimated by detecting only the presence or absence of condensed water in a specific portion where condensed water is unlikely to be generated in the heat exchanger.

The control device 90 is connected to the compressor 11. The control device 90 controls the operation of the compressor 11 according to the necessity of the air conditioning operation. That is, when the air conditioning operation is unnecessary, the compressor 11 is stopped. On the other hand, when air conditioning operation is required, the compressor 11 is operated. Further, when the temperature difference between the target temperature and the actual temperature is large in the air-conditioning operation, the output of the compressor 11 is increased to control the temperature in the vehicle interior so as to approach the target temperature quickly.

The control device 90 is connected to the first blower 32 and the second blower 42. The control device 90 controls the rotation speed of the first blower 32 and the rotation speed of the second blower 42 so as to approach the target air volume. That is, stop control and output control of the first blower 32 and the second blower 42 are performed. In particular, in order to increase the amount of air blown into the vehicle interior when the pressure loss when passing through the heat exchanger increases due to the generation of condensed water in the first heat exchanger 31 and the second heat exchanger 41. It is controlled to increase the rotation speed of the first blower 32 or the second blower 42.

The control device 90 is connected to the first interior door 35, the first outdoor door 36, the second interior door 45, and the second outdoor door 46. The control device 90 controls the opening degree of each of the first interior door 35, the first outdoor door 36, the second interior door 45, and the second outdoor door 46 according to the air conditioning operation. That is, by adjusting the opening degree of each door, the amount of air that has passed through the evaporator and cooled and the amount of air that has passed through the condenser and heated has flowed into the passenger compartment and the amount of air that has flowed out of the passenger compartment. And control.

The control device 90 is connected to the four-way valve 25. The control device 90 switches the four-way valve 25 to switch and control the direction in which the refrigerant flows. That is, which heat exchanger is evaporated by switching between flowing the liquid refrigerant, which has become easier to evaporate due to the flow through the decompression device 12, to the first heat exchanger 31 and the second heat exchanger 41. Switch whether to use it as a vessel.

In the cooling operation, air conditioning is performed by taking out the cold air cooled by the evaporator, which is the cooling source, and flowing it into the vehicle interior. On the other hand, in the heating operation, the hot air heated by the condenser, which is the heating source, is taken out and flowed into the vehicle interior to perform air conditioning. However, instead of using only the condenser as the heating source, a device such as a compressor 11 that generates heat when driven may be used as the heating source. In the dehumidifying operation, air is blown to an evaporator having a low temperature, so that the moisture contained in the air is condensed on the outer surface of the evaporator and taken out as condensed water. This reduces the amount of water vapor contained in the air and dehumidifies it. The first heat exchanger 31 and the second heat exchanger 41 are switched between a state of functioning as an evaporator and a state of functioning as a condenser by switching the refrigerant flow path by the four-way valve 25. When the first heat exchanger 31 functions as a condenser, the second heat exchanger 41 functions as an evaporator. On the other hand, when the first heat exchanger 31 functions as an evaporator, the second heat exchanger 41 functions as a condenser.

Switching of the refrigerant flow path by the four-way valve 25 and switching of the air flow path by each door will be described below by taking as an example during cooling operation. In FIG. 5, the four-way valve 25 communicates the discharge side pipe of the compressor 11 with the first heat exchanger 31. Further, the four-way valve 25 communicates the suction side pipe of the compressor 11 with the second heat exchanger 41. This state shows the state of the first refrigerant mode in which the first heat exchanger 31 is used as a condenser and the second heat exchanger 41 is used as an evaporator. Further, the first outdoor door 36 and the second interior door 45 are in the open state, and the first interior door 35 and the second outdoor door 46 are in the closed state. This state indicates a second ventilation mode in which the air exchanged for heat by the second heat exchanger 41 is blown into the room.

The flow of the refrigerant in the first refrigerant mode will be described below. The high-temperature and high-pressure gaseous refrigerant discharged from the compressor 11 flows into the first heat exchanger 31 via the four-way valve 25. In the first heat exchanger 31, the high-temperature and high-pressure refrigerant exchanges heat with the surrounding air, thereby heating the surrounding air and lowering the temperature of the refrigerant to condense the gas into a liquid. That is, the first heat exchanger 31 functions as a condenser.

The liquid refrigerant that has flowed out of the first heat exchanger 31 that functions as a condenser is decompressed by the decompression device 12 and is in a state of being easily evaporated. After that, the refrigerant flows into the second heat exchanger 41. In the second heat exchanger 41, the low-pressure refrigerant exchanges heat with the surrounding air to take heat of vaporization and cool the surrounding air, and the refrigerant vaporizes from a liquid to a gas. That is, the second heat exchanger 41 functions as an evaporator.

The gaseous refrigerant flowing out of the second heat exchanger 41 that functions as an evaporator is sucked into the compressor 11 via the four-way valve 25 and compressed again. As a result, the operation of a series of refrigeration cycles is repeated. Here, a gas-liquid separator may be provided in the refrigerant pipe 20 from the second heat exchanger 41 to the compressor 11. The gas-liquid separator can separate the gaseous refrigerant and the liquid refrigerant and allow only the gaseous refrigerant to flow through the compressor 11. Therefore, it is possible to prevent the refrigerating cycle device 10 from malfunctioning due to the liquid back phenomenon in which the liquid refrigerant is sucked into the compressor 11.

The air flow in the second blowing mode will be described below. While the refrigeration cycle device 10 is being operated, the first blower 32 and the second blower 42 are driven. By driving the first blower 32, the air heated by the heat exchange with the first heat exchanger 31 functioning as a condenser is discharged from the first outdoor door 36 to the outside. This prevents the air whose temperature has risen from staying around the first heat exchanger 31, and can efficiently exchange heat between the air before the temperature rise and the first heat exchanger 31.

By driving the second blower 42, the air cooled by the heat exchange with the second heat exchanger 41 that functions as an evaporator is sent out from the second interior door 45 to the indoor communication port 61 that communicates with the room. As a result, cold air is blown into the room to perform cooling operation. Further, it is possible to prevent the air whose temperature has dropped from staying around the second heat exchanger 41, and to efficiently exchange heat between the air before the temperature drop and the second heat exchanger 41.

Here, by slightly opening the first interior door 35, the hot air heated by the first heat exchanger 31 may be mixed with the cold air cooled by the second heat exchanger 41. According to this, the temperature of the conditioned air can be adjusted before flowing into the indoor communication port 61. Therefore, the air conditioning operation can be performed at an appropriate blowout temperature.

In FIG. 6, the four-way valve 25 communicates the discharge side pipe of the compressor 11 with the second heat exchanger 41. Further, the four-way valve 25 communicates the suction side pipe of the compressor 11 with the first heat exchanger 31. This state shows the state of the second refrigerant mode in which the first heat exchanger 31 is used as an evaporator and the second heat exchanger 41 is used as a condenser. In the second refrigerant mode, which heat exchanger, the first heat exchanger 31 or the second heat exchanger 41, is used as the evaporator is the opposite of the first refrigerant mode.

Further, the first interior door 35 and the second outdoor door 46 are in the open state, and the first outdoor door 36 and the second interior door 45 are in the closed state. This state indicates the first ventilation mode in which the air heat-exchanged by the first heat exchanger 31 is blown into the room. In the first blower mode, which of the heat exchangers of the first heat exchanger 31 and the second heat exchanger 41 is sent to the vehicle interior is the opposite of the second blower mode.

The flow of the refrigerant in the second refrigerant mode will be described below. The high-temperature and high-pressure gaseous refrigerant discharged from the compressor 11 flows into the second heat exchanger 41 via the four-way valve 25. In the second heat exchanger 41, the high-temperature and high-pressure refrigerant exchanges heat with the surrounding air, thereby heating the surrounding air and lowering the temperature of the refrigerant to condense the gas into a liquid. That is, the second heat exchanger 41 functions as a condenser.

The liquid refrigerant that has flowed out of the second heat exchanger 41 that functions as a condenser is decompressed by the decompression device 12 and is in a state of being easily evaporated. After that, the refrigerant flows into the first heat exchanger 31. In the first heat exchanger 31, the low-pressure refrigerant exchanges heat with the surrounding air to take heat of vaporization and cool the surrounding air, and the refrigerant vaporizes from a liquid to a gas. That is, the first heat exchanger 31 functions as an evaporator.

The gaseous refrigerant flowing out of the first heat exchanger 31 functioning as an evaporator is sucked into the compressor 11 via the four-way valve 25 and compressed again. As a result, the operation of a series of refrigeration cycles is repeated. Here, a gas-liquid separator may be provided in the refrigerant pipe 20 from the first heat exchanger 31 to the compressor 11.

The air flow in the first blast mode will be described below. While operating the refrigeration cycle device 10, the first blower 32 and the second blower 42 are driven. By driving the second blower 42, the air heated by the heat exchange with the second heat exchanger 41 that functions as a condenser is discharged from the second outdoor door 46 to the outside. This prevents the air whose temperature has risen from staying around the second heat exchanger 41, and can efficiently exchange heat between the air before the temperature rise and the second heat exchanger 41.

By driving the first blower 32, the air cooled by the heat exchange with the first heat exchanger 31 that functions as an evaporator is sent out from the first interior door 35 to the indoor communication port 61 that communicates with the room. As a result, cold air is blown into the room to perform cooling operation. Further, it is possible to prevent the air whose temperature has dropped from staying around the first heat exchanger 31 and efficiently exchange heat between the air before the temperature drop and the first heat exchanger 31.

Here, by slightly opening the second interior door 45, the hot air heated by the second heat exchanger 41 may be mixed with the cold air cooled by the first heat exchanger 31. Thereby, the temperature of the air conditioning air can be adjusted before flowing into the indoor communication port 61. Therefore, the air conditioning operation can be performed at an appropriate blowout temperature.

Switching between the four-way valve 25, the first interior door 35, the first outdoor door 36, the second interior door 45, and the second outdoor door 46 is the detection result of condensed water in the first water sensor 39 and the second water sensor 49. Control based on. That is, when the first water sensor 39 detects condensed water, the four-way valve 25 is switched so that the first heat exchanger 31 is used as a condenser instead of being used as an evaporator. In other words, the first heat exchanger 31 is arranged not on the upstream side of the decompression device 12 but on the downstream side. At the same time, the first interior door 35, the first outdoor door 36, the second interior door 45, and the second outdoor door 46 are switched to control so that the cold air that has passed through the evaporator is blown into the room.

Here, the timing of switching the four-way valve 25 and the timing of switching each door may be staggered. For example, until the temperatures of the first heat exchanger 31 and the second heat exchanger 41 reach a predetermined temperature range, the doors are not switched and the first blower 32 and the second blower 42 are stopped. .. According to this, it is possible to prevent the high temperature air from being blown into the room in the transition state until the temperature of the second heat exchanger 41 functioning as the evaporator drops.

On the other hand, when the second water sensor 49 detects condensed water, the four-way valve 25 is switched so that the second heat exchanger 41 is used as a condenser instead of being used as an evaporator. In other words, the second heat exchanger 41 is arranged not on the upstream side of the decompression device 12 but on the downstream side. At the same time, the opening and closing of the first interior door 35, the first outdoor door 36, the second interior door 45, and the second outdoor door 46 are switched to control the cold air passing through the evaporator to be blown into the room.

As described above, the switching control is repeated so that the heat exchanger in which the condensed water is detected is used as the condenser and the heat exchanger in which the condensed water is not detected is used as the evaporator. Further, the cooling operation is continued by switching the opening and closing of each door so that the air exchanged with the heat exchanger always used as the evaporator is sent toward the indoor communication port 61. Here, when the heating operation is performed, the heating operation is continued by switching each door so as to always send the heat exchanged air with the heat exchanger used as the condenser toward the indoor communication port 61. That is, in the heating operation, when operating in the first refrigerant mode, warm air is blown into the vehicle interior by using the first blowing mode. Alternatively, when operating in the second refrigerant mode, warm air is blown into the vehicle interior using the second blower mode.

The treatment operation of the condensed water of the vehicle air conditioner 1 will be described below by taking as an example during the cooling operation. By operating in the first refrigerant mode, the second heat exchanger 41, which functions as an evaporator, condenses the moisture contained in the air by heat exchange with the air, and the second heat exchanger 41 Generated as condensed water on the surface. The condensed water generated on the surface of the second heat exchanger 41 is maintained in a state of adhering to the surface of the second heat exchanger 41 up to a predetermined amount. Therefore, the amount of condensed water held on the surface of the second heat exchanger 41 increases as the heat exchange is performed. Here, when condensed water exceeding the maximum water retention amount that can be retained by the second heat exchanger 41 is generated on the surface, the condensed water becomes water droplets and drips from the surface of the second heat exchanger 41.

The second water sensor 49 detects the amount of condensed water generated on the surface of the second heat exchanger 41. When the amount of condensed water detected by the second water sensor 49 exceeds a predetermined amount, the control device 90 controls the four-way valve 25 to switch the refrigerant mode from the first refrigerant mode to the second refrigerant mode. Here, the predetermined amount is a value set smaller than the maximum water retention amount of the second heat exchanger 41, and is condensed in the stage before the condensed water drips from the surface of the second heat exchanger 41 as water droplets. The amount of water allowed. For example, when the maximum water retention amount in the second heat exchanger 41 is 50 g, the predetermined amount can be set to 45 g, which is a value slightly smaller than the maximum water retention amount. However, since the predetermined amount varies depending on various conditions such as the size of the second heat exchanger 41, the air volume of the second blower 42, and the amount of water contained in the air before heat exchange, it is a value that can be arbitrarily set. If it is permissible for the condensed water to drip from the second heat exchanger 41 to some extent, an amount equal to or greater than the maximum water retention amount may be set as a predetermined amount.

By switching from the first refrigerant mode to the second refrigerant mode, the high-temperature and high-pressure gas refrigerant discharged from the compressor 11 flows into the second heat exchanger 41. Therefore, in the second heat exchanger 41, the refrigerant flowing inside and the condensed water exchange heat, the temperature of the refrigerant drops, and the gas is condensed into a liquid. On the other hand, the condensed water is evaporated into the air by being heated by the exhaust heat of the refrigerant and is removed from the surface of the second heat exchanger 41. In the second heat exchanger 41, the heat exchange target with the refrigerant is not only air, but the heat exchange target with the refrigerant is condensed water and air. Therefore, since a large amount of heat can be exchanged including the sensible heat component due to the temperature change of water and the latent heat component due to evaporation of water, the heat exchange efficiency in the second heat exchanger 41 can be improved.

Simultaneously with or after switching the refrigerant mode, the control device 90 switches the blowing mode from the second blowing mode to the first blowing mode. As a result, the air that has exchanged heat with the first heat exchanger 31 that functions as an evaporator can be blown into the vehicle interior. Further, the air that has exchanged heat with the second heat exchanger 41 that functions as a condenser can be blown to the outside of the vehicle interior. Here, the air that has been heat-exchanged with the second heat exchanger 41 has a high temperature, so that the amount of saturated water vapor is large. Further, the air that has exchanged heat with the second heat exchanger 41 contains a large amount of evaporated condensed water. Therefore, since the air is blown to the outside of the vehicle interior in a state where the air contains a large amount of water, the water can be efficiently removed to the outside of the vehicle interior to treat the condensed water.

By switching from the first refrigerant mode to the second refrigerant mode and switching from the second blower mode to the first blower mode as described above, the condensed water adhering to the surface of the second heat exchanger 41 utilizes the exhaust heat of the refrigerant. Can be processed efficiently. However, water will be newly condensed on the surface of the first heat exchanger 31. Therefore, when the amount of condensed water detected by the first water sensor 39 exceeds a predetermined amount, the condensed water generated on the surface of the first heat exchanger 31 is treated by switching to the first refrigerant mode again. Will be done.

According to the above-described embodiment, when the second water sensor 49 detects condensed water, the control device 90 controls the four-way valve 25 to switch from the first refrigerant mode to the second refrigerant mode. Further, the opening / closing of each door such as the first interior door 35 is controlled to switch from the second ventilation mode to the first ventilation mode. Therefore, the condensed water can be treated by exchanging heat with the high-temperature refrigerant for the condensed water generated on the surface of the second heat exchanger 41. Therefore, the condensed water can be effectively treated by using the waste heat of the refrigerant. Therefore, since the configuration used for treating condensed water such as a heater and a gutter can be omitted, the vehicle air conditioner 1 can be easily miniaturized. In particular, in a small air-conditioning device such as a seat air-conditioning device in which parts constituting the refrigeration cycle device 10 are housed in an air-conditioning case 51, it is extremely important to reduce the number of parts and reduce the size. Further, since it is not necessary to drive a heater or the like for the purpose of treating the condensed water, it is not necessary to consume electric power or the like for the treatment of the condensed water. Alternatively, even when a heater or the like is used in combination with the treatment of the condensed water, the output and the driving time of the heater can be reduced by the amount that the condensed water can be treated by using the heat of the refrigerant.

Further, by sending the air cooled by the first heat exchanger 31 into the room, the cooling operation can be performed while treating the condensed water generated in the second heat exchanger 41. Therefore, even during the treatment of the condensed water, it is easy to secure the time for performing the cooling operation and to secure the total cooling operation time for a long time. Therefore, the temperature inside the vehicle interior can be quickly brought close to the target temperature.

The control device 90 controls the four-way valve 25 to switch between the first refrigerant mode and the second refrigerant mode, and at substantially the same time, controls the first interior door 35 and the second interior door 45 to perform the first ventilation mode and the second. 2 Switching between the ventilation mode. Therefore, the air conditioning operation can be continued even at the timing of switching between the refrigerant mode and the ventilation mode. Here, the control device 90 controls the four-way valve 25 to switch between the first refrigerant mode and the second refrigerant mode, and then controls the first interior door 35 and the second interior door 45 to perform the first ventilation mode. And the second ventilation mode may be switched. In this case, the air blow to the vehicle interior can be stopped in the transient state where the temperature of the heat exchanger is changing. Therefore, at the timing of switching between the refrigerant mode and the ventilation mode, it is possible to prevent the sudden blow of hot air during the cooling operation and the sudden blow of the cold air during the heating operation, so that the air conditioning is comfortable for the occupants. Easy to provide.

Condensed water is detected by the first water sensor 39 and the second water sensor 49. Therefore, the amount of condensed water actually generated on the surface of the heat exchanger can be directly detected. Therefore, it is possible to accurately grasp the amount of condensed water generated and perform switching control by the control device 90.

The first water sensor 39 is located below the gravity direction in the first heat exchanger 31. Therefore, even in a state where the condensed water generated on the surface of the first heat exchanger 31 is attracted by gravity and is about to drip, it is easy to detect the condensed water with high accuracy.

It includes a first interior door 35, a first outdoor door 36, a second interior door 45, and a second outdoor door 46. Therefore, in the first air blowing mode, the air that has exchanged heat with the first heat exchanger 31 is blown into the room from the indoor communication port 61, and the air that has exchanged heat with the second heat exchanger 41 is sent to the second outdoor communication port 43. Can be blown out of the room. Therefore, the waste heat generated by the second heat exchanger 41 can be discharged to the outside to improve the operating efficiency of the refrigeration cycle device 10. Similarly, in the second blower mode, the exhaust heat generated in the first heat exchanger 31 can be discharged to the outside to improve the operating efficiency of the refrigeration cycle device 10.

It includes a first interior door 35 and a second interior door 45. Therefore, by adjusting the opening degree between the first interior door 35 and the second interior door 45 and mixing the cold air and the hot air, the air-conditioned air adjusted to the optimum temperature for the occupant is blown into the passenger compartment. be able to.

Second Embodiment This embodiment is a modification based on the preceding embodiment as a basic embodiment. In this embodiment, one blower 232 is used to blow air to both the first heat exchanger 31 and the second heat exchanger 41.

In FIG. 7, the vehicle air conditioner 1 is provided with a blower 232 substantially in the center of the air conditioner case 51. The blower 232 is a centrifugal blower that sucks air from an intake port provided on the bottom surface of the air conditioning case 51 and blows air radially away from the central axis.

The first heat exchanger 31 and the second heat exchanger 41 are provided along the wall surface of the air conditioning case 51. The first heat exchanger 31 and the second heat exchanger 41 are arranged at substantially equal distances from the blower 232. The first heat exchanger 31 and the second heat exchanger 41 are arranged at positions facing each other. In other words, the blower 232 is provided between the first heat exchanger 31 and the second heat exchanger 41.

The air-conditioning case 51 includes four communication ports, that is, the first indoor communication port 237, the first outdoor communication port 233, the second indoor communication port 247, and the second outdoor communication port 243. In the air-conditioning case 51, the inside and the outside of the air-conditioning case 51 are communicated by these four communication ports. The first indoor communication port 237 and the second indoor communication port 247 are openings communicating with the vehicle interior. The first outdoor communication port 233 and the second outdoor communication port 243 are openings communicating with the outside of the vehicle interior. The air conditioning case 51 includes a first indoor door 235 that opens and closes the first indoor communication port 237, and a first outdoor door 236 that opens and closes the first outdoor communication port 233. The air conditioning case 51 includes a second indoor door 245 that opens and closes the second indoor communication port 247, and a second outdoor door 246 that opens and closes the second outdoor communication port 243. The first interior door 235 and the second interior door 245 provide a blower switching device.

The first interior door 235 and the first outdoor door 236 are provided adjacent to each other. The first interior door 235 and the first outdoor door 236 are provided on the projection surface from the blower 232 to the first heat exchanger 31 in the air conditioning case 51. In other words, the first heat exchanger 31 is provided between the blower 232 and the first interior door 235 and the first outdoor door 236. Therefore, the air flowing from the blower 232 toward the first interior door 235 or the first outdoor door 236 passes through the first heat exchanger 31.

The second interior door 245 and the second outdoor door 246 are provided adjacent to each other. The second interior door 245 and the second outdoor door 246 are provided on the projection surface from the blower 232 to the second heat exchanger 41 in the air conditioning case 51. In other words, the second heat exchanger 41 is provided between the blower 232 and the second interior door 245 and the second outdoor door 246. Therefore, the air flowing from the blower 232 toward the second interior door 245 or the second outdoor door 246 passes through the second heat exchanger 41.

The blower 232 is provided with an upstream sensor 271. The upstream sensor 271 is a sensor that measures the physical quantity of the upstream air before heat exchange with the first heat exchanger 31 and the second heat exchanger 41. The physical quantity measured by the upstream sensor 271 is, for example, the temperature, humidity, or flow rate of air. The upstream sensor 271 is a sensor unit that integrally includes a temperature sensor, a humidity sensor, and a flow rate sensor. The upstream sensor 271 provides a water detection device.

The air conditioning case 51 is provided with a first downstream sensor 238 and a second downstream sensor 248. The first downstream sensor 238 is provided between the first interior door 235 and the first outdoor door 236 and the first heat exchanger 31. The first downstream sensor 238 is a sensor that measures the physical quantity of the downstream air after heat exchange with the first heat exchanger 31. The first downstream sensor 238 measures physical quantities such as air temperature, humidity, and flow rate. The first downstream sensor 238 is a sensor unit integrally including a temperature sensor, a humidity sensor, and a flow rate sensor. The first downstream sensor 238 provides a water detection device.

The second downstream sensor 248 is provided between the second interior door 245 and the second outdoor door 246 and the second heat exchanger 41. The second downstream sensor 248 is a sensor that measures the physical quantity of the downstream air after heat exchange with the second heat exchanger 41. The second downstream sensor 248 measures physical quantities such as air temperature, humidity, and flow rate. The second downstream sensor 248 is a sensor unit integrally including a temperature sensor, a humidity sensor, and a flow rate sensor. The second downstream sensor 248 provides a water detection device.

The switching of the refrigerant mode by the four-way valve 25 and the switching of the ventilation mode by each door will be described below by taking the cooling operation as an example. In FIG. 8, the four-way valve 25 shows the state of the first refrigerant mode in which the first heat exchanger 31 is used as a condenser and the second heat exchanger 41 is used as an evaporator. Further, the first outdoor door 236 and the second interior door 245 are in the open state, and the first interior door 235 and the second interior door 246 are in the closed state. This state indicates a second ventilation mode in which the air exchanged for heat by the second heat exchanger 41 is blown into the room.

The air flow in the second blowing mode will be described below. While operating the refrigeration cycle device 10, the blower 232 is driven. The temperature, humidity and flow rate of the air blown from the blower 232 are measured by the upstream sensor 271. The blower 232 sends wind to the first heat exchanger 31 and the second heat exchanger 41 at the same time. At this time, the blower 232 may be provided with a louver to control the blowing direction of the wind. According to this, the wind can be sent to the first heat exchanger 31 and the second heat exchanger 41. Therefore, the amount of wind that does not go to the first heat exchanger 31 and the second heat exchanger 41 is reduced, and the heat exchange between the refrigerant and the air in the first heat exchanger 31 and the second heat exchanger 41 is efficient. Can be done in a targeted manner.

By driving the blower 232, the air heated by the heat exchange with the first heat exchanger 31 that functions as a condenser is discharged from the first outdoor door 236 to the outside. This prevents the air whose temperature has risen from staying around the first heat exchanger 31, and can efficiently exchange heat with the air before the temperature rise with the first heat exchanger 31.

Further, by driving the blower 232, the air cooled by the heat exchange with the second heat exchanger 41 functioning as an evaporator is sent out into the room from the second interior door 245. In this way, cold air is blown into the passenger compartment to perform cooling operation. Further, it is possible to prevent the air whose temperature has dropped from staying around the second heat exchanger 41, and to efficiently exchange heat between the air before the temperature drop and the second heat exchanger 41. The temperature, humidity, and flow rate of the air cooled by the second heat exchanger 41 are measured by the second downstream sensor 248.

In FIG. 9, the four-way valve 25 shows the state of the second refrigerant mode in which the first heat exchanger 31 is used as an evaporator and the second heat exchanger 41 is used as a condenser. In the second refrigerant mode, which heat exchanger of the first heat exchanger 31 and the second heat exchanger 41 is used as the evaporator has the opposite relationship to the first refrigerant mode. Further, the first interior door 235 and the second outdoor door 246 are in the open state, and the first outdoor door 236 and the second interior door 245 are in the closed state. This state indicates the first ventilation mode in which the air heat-exchanged by the first heat exchanger 31 is blown into the room. In the first blower mode, which of the heat exchangers of the first heat exchanger 31 and the second heat exchanger 41 is sent to the vehicle interior has the opposite relationship to the second blower mode.

The air flow in the first blast mode will be described below. While operating the refrigeration cycle device 10, the blower 232 is driven. The temperature, humidity, and flow rate of the air blown from the blower 232 are measured by the upstream sensor 271. By driving the blower 232, the air heated by the heat exchange with the second heat exchanger 41 that functions as a condenser is discharged from the second outdoor door 246 to the outside. This prevents the air whose temperature has risen from staying around the second heat exchanger 41, and can efficiently exchange heat with the air before the temperature rise with the second heat exchanger 41.

Further, by driving the blower 232, the air cooled by the heat exchange with the first heat exchanger 31 functioning as an evaporator is sent out into the room from the first interior door 235. As a result, cold air is blown into the vehicle interior to perform cooling operation. Further, it is possible to prevent the air whose temperature has dropped from staying around the first heat exchanger 31 and efficiently exchange heat between the air before the temperature drop and the first heat exchanger 31. The temperature, humidity, and flow rate of the air cooled by the first heat exchanger 31 are measured by the first downstream sensor 238.

Switching between the four-way valve 25, the first interior door 235, the first outdoor door 236, the second interior door 245, and the second outdoor door 246 is the air in the upstream sensor 271 and the first downstream sensor 238 or the second downstream sensor 248. Control based on the detection result of the physical quantity of. That is, in the first refrigerant mode in which the second heat exchanger 41 functions as an evaporator, the amount of condensed water is obtained from the physical quantity of air measured by the upstream sensor 271 and the physical quantity of air measured by the second downstream sensor 248. Is calculated. On the other hand, in the second refrigerant mode in which the first heat exchanger 31 functions as an evaporator, the amount of condensed water is determined from the physical quantity of air measured by the upstream sensor 271 and the physical quantity of air measured by the first downstream sensor 238. Is calculated.

The calculation method of condensed water is shown below using a specific example. For example, when the temperature of the air measured by the upstream sensor 271 is 25 ° C., the humidity is 50%, and the flow rate is 30 m ³ / h, the amount of water contained in the air before the heat exchange by the second heat exchanger 41 is performed. Is calculated as 345 g / h. This indicates that the air before heat exchange in the second heat exchanger 41 has a total of 345 g of water per hour. On the other hand, when the temperature of the air measured by the second downstream sensor 248 is 5 ° C., the humidity is 100%, and the flow rate is 30 m ³ / h, the air after heat exchange by the second heat exchanger 41 has. The water content is calculated to be 204 g / h. This indicates that the air after heat exchange in the second heat exchanger 41 has a total of 204 g of water per hour. Therefore, it can be calculated that 141 g of water is lost from the air in total per hour by exchanging heat with the second heat exchanger 41. Assuming that all the water lost from the air is condensed on the surface of the second heat exchanger 41, it is estimated that 141 g of condensed water is generated in the second heat exchanger 41 in total per hour. ..

Here, when the maximum water retention amount of the second heat exchanger 41 is, for example, 50 g, it can be calculated that the maximum water retention amount is reached in about 21 minutes. If condensed water is generated on the surface of the second heat exchanger 41 in excess of the maximum water retention amount, the second heat exchanger 41 cannot completely retain the condensed water, and the condensed water drips from the second heat exchanger 41. .. Therefore, the first state and the second state are switched within a range not exceeding the maximum water retention amount in the second heat exchanger 41. That is, the four-way valve 25 is switched so that the second heat exchanger 41 functions as a condenser instead of an evaporator.

However, the physical quantity of air measured by the upstream sensor 271 and the second downstream sensor 248 is not always constant. Therefore, the water content is calculated using the latest physical quantity of air at each timing measured by the upstream sensor 271 and the second downstream sensor 248, and the calculated water content is integrated on the surface of the second heat exchanger 41. It is preferable to estimate the amount of condensed water generated at the present time.

Further, the water content in the air may be estimated from physical quantities other than the temperature, humidity and flow rate of the air, and the change in the water content before and after heat exchange with the heat exchanger may be estimated. Further, the estimation accuracy regarding the generation of condensed water can be improved by appropriately correcting the method for estimating the condensed water according to the detection accuracy of the upstream sensor 271, the first downstream sensor 238, and the second downstream sensor 248. preferable.

According to the above-described embodiment, the condensed water generated in the first heat exchanger 31 or the second heat exchanger 41 from the physical quantity of air measured by the upstream sensor 271 and the first downstream sensor 238 or the second downstream sensor 248. Estimates the amount of. Therefore, since it is only necessary to measure the physical amount of air before and after heat exchange with the heat exchanger, it is not always necessary to provide a sensor near the first heat exchanger 31 and the second heat exchanger 41. In other words, it is possible to increase the degree of freedom in the position of the water detection device such as the upstream sensor 271, the first downstream sensor 238, and the second downstream sensor 248.

The blower 232 is provided between the first heat exchanger 31 and the second heat exchanger 41. Therefore, one blower 232 can blow air to both the first heat exchanger 31 and the second heat exchanger 41. Therefore, it is easier to miniaturize the vehicle air conditioner 1 as compared with the case where a plurality of blowers are provided.

Third Embodiment This embodiment is a modification based on the preceding embodiment. In this embodiment, using a plurality of four-way valves 325, the flow directions of the refrigerant inside the first heat exchanger 31 and the inside of the second heat exchanger 41 are the same in the first refrigerant mode and the second refrigerant mode. It is oriented.

In FIG. 10, the refrigerant pipe 20 includes four four-way valves 325, which are a first four-way valve 325a, a second four-way valve 325b, a third four-way valve 325c, and a fourth four-way valve 325d. The four-way valve 325 provides a refrigerant switching device.

The first four-way valve 325a is connected to the upstream pipe and the downstream pipe of the compressor 11. In other words, the refrigerant flows out of the first four-way valve 325a and flows into the compressor 11. Further, the refrigerant flows out of the compressor 11 and flows into the first four-way valve 325a. The second four-way valve 325b is connected to the upstream pipe and the downstream pipe of the first heat exchanger 31. In other words, the refrigerant flows out of the second four-way valve 325b and flows into the first heat exchanger 31. Further, the refrigerant flows out of the first heat exchanger 31 and flows into the second four-way valve 325b. The third four-way valve 325c is connected to the upstream pipe and the downstream pipe of the decompression device 12. In other words, the refrigerant flows out of the third four-way valve 325c and flows into the decompression device 12. Further, the refrigerant flows out of the pressure reducing device 12 and flows into the third four-way valve 325c. The fourth four-way valve 325d is connected to the upstream pipe and the downstream pipe of the second heat exchanger 41. In other words, the refrigerant flows out of the fourth four-way valve 325d and flows into the second heat exchanger 41. Further, the refrigerant flows out from the second heat exchanger 41 and flows into the fourth four-way valve 325d.

FIG. 10 shows the flow of refrigerant in the first refrigerant mode in which the first heat exchanger 31 functions as a condenser and the second heat exchanger 41 functions as an evaporator. The flow of the refrigerant in the first refrigerant mode will be described below.

The refrigerant flowing out of the compressor 11 flows into the first heat exchanger 31 via the first four-way valve 325a and the second four-way valve 325b and is condensed into a liquid refrigerant. After that, the refrigerant flowing out of the first heat exchanger 31 flows into the decompression device 12 via the second four-way valve 325b and the third four-way valve 325c. Here, in the first heat exchanger 31, the refrigerant inlet pipe is arranged on the first indoor door 235 side, and the refrigerant outlet pipe is arranged on the first outdoor door 236 side.

The refrigerant decompressed by the decompression device 12 and flows out of the decompression device 12 flows into the second heat exchanger 41 via the third four-way valve 325c and the fourth four-way valve 325d and evaporates into the gaseous refrigerant. After that, the refrigerant flowing out of the second heat exchanger 41 flows into the compressor 11 via the fourth four-way valve 325d and the first four-way valve 325a, so that a series of refrigeration cycles are repeated. Here, in the second heat exchanger 41, the refrigerant inlet pipe is arranged on the second outdoor door 246 side, and the refrigerant outlet pipe is arranged on the second indoor door 245 side.

FIG. 11 shows the flow of refrigerant in the second refrigerant mode in which the first heat exchanger 31 functions as an evaporator and the second heat exchanger 41 functions as a condenser. The flow of the refrigerant in the second refrigerant mode will be described below.

The refrigerant flowing out of the compressor 11 flows into the second heat exchanger 41 via the first four-way valve 325a and the fourth four-way valve 325d, and is condensed into a liquid refrigerant. After that, the refrigerant flowing out of the second heat exchanger 41 flows into the decompression device 12 via the fourth four-way valve 325d and the third four-way valve 325c. Here, in the second heat exchanger 41, the refrigerant inlet pipe is arranged on the second outdoor door 246 side, and the refrigerant outlet pipe is arranged on the second indoor door 245 side.

The refrigerant decompressed by the decompression device 12 and flows out of the decompression device 12 flows into the first heat exchanger 31 via the third four-way valve 325c and the second four-way valve 325b and evaporates into a gaseous refrigerant. After that, the refrigerant flowing out of the first heat exchanger 31 flows into the compressor 11 via the second four-way valve 325b and the first four-way valve 325a, so that a series of refrigeration cycles are repeated. Here, in the first heat exchanger 31, the refrigerant inlet pipe is arranged on the first indoor door 235 side, and the refrigerant outlet pipe is arranged on the first outdoor door 236 side.

As described above, the first heat exchanger 31 and the second heat exchanger 41 have a configuration in which the inlet pipe and the outlet pipe do not switch even if the refrigerant mode is switched between the first refrigerant mode and the second refrigerant mode. Is. In other words, the first heat exchanger 31 and the second heat exchanger 41 have a configuration in which the flow direction of the refrigerant does not change depending on whether the first heat exchanger 31 or the second heat exchanger 41 functions as a condenser or an evaporation line.

Here, when the decompression device 12 is a device such as a capillary tube or an orifice that can depressurize without depending on the flow direction of the refrigerant, the third four-way valve 325c can be omitted.

Switching between the refrigerant mode and the blower mode is performed based on the output of the blower 232. The mode switching will be described below by taking as an example the case of switching from the state in which the cooling operation is performed in the first refrigerant mode and the second blowing mode to the state in which the cooling operation is performed in the second refrigerant mode and the first blowing mode.

Since it is in the first refrigerant mode, the first heat exchanger 31 functions as a condenser, and the second heat exchanger 41 functions as an evaporator. Condensed water is gradually generated on the surface of the second heat exchanger 41, and the surface of the second heat exchanger 41 is partially covered with the condensed water. At this time, since the condensed water also adheres to the surface of the fin forming a part of the second heat exchanger 41, the ventilation portion in the second heat exchanger 41 is partially clogged by the condensed water. In particular, when a minute hole is provided on the surface of the fin in order to improve the efficiency of heat exchange, clogging is likely to occur in the minute hole.

When the ventilation portion of the second heat exchanger 41 is clogged, the ventilation resistance increases as compared with the case where the clogging is not caused. Therefore, even if the rotation speed of the blower 232 is the same, the amount of cold air blown into the vehicle interior is reduced by the amount of increased ventilation resistance. In other words, it is necessary to increase the output of the blower 232 in order to secure the target blown air volume. When switching the refrigerant mode, the output change of the blower 232 is used.

The control device 90 is the output of the blower 232 in the state where the condensed water is not generated in the second heat exchanger 41, and the blower 232 in the state where the condensed water is generated up to the maximum water retention amount in the second heat exchanger 41. Get the difference from the output. Using the obtained difference in the output of the blower 232, the amount of condensed water generated from the current output of the blower 232 is estimated. In other words, it can be estimated that the closer the output of the blower 232 is to the output in the state where the condensed water is generated up to the maximum water retention amount, the more the condensed water is generated. Therefore, when the output of the blower 232 exceeds a predetermined value set based on the output in the state where the condensed water is generated up to the maximum water retention amount, the first refrigerant mode is switched to the second refrigerant mode.

According to the above-described embodiment, the directions of the refrigerant flowing inside the first heat exchanger 31 and the second heat exchanger 41 do not change before and after switching between the first refrigerant mode and the second refrigerant mode. Therefore, by optimizing the flow of the refrigerant, the air conditioner for vehicles has a stable and high heat exchange efficiency without changing the heat exchange efficiency between the refrigerant and the air between the first refrigerant mode and the second refrigerant mode. Easy to drive 1.

The amount of condensed water generated in the first heat exchanger 31 or the second heat exchanger 41 is estimated based on the output of the blower 232. Therefore, it is not necessary to directly attach a sensor for detecting condensed water to the first heat exchanger 31 or the second heat exchanger 41. Therefore, the degree of freedom in the layout of the water detection device constituting the vehicle air conditioner 1 can be increased.

Other Embodiments The disclosure in this specification, drawings and the like is not limited to the exemplified embodiments. Disclosures include exemplary embodiments and modifications by those skilled in the art based on them. For example, the disclosure is not limited to the parts and / or combinations of elements shown in the embodiments. Disclosure can be carried out in various combinations. Disclosures can have additional parts that can be added to the embodiments. Disclosures include those in which the parts and / or elements of the embodiment are omitted. Disclosures include replacements or combinations of parts and / or elements between one embodiment and the other. The technical scope disclosed is not limited to the description of the embodiments. Some technical scopes disclosed are indicated by the claims description and should be understood to include all modifications within the meaning and scope equivalent to the claims description.

1 Vehicle air conditioner, 10 Refrigeration cycle device, 11 Compressor, 12 Decompression device, 25 Four-way valve (fluid switching device), 31 First heat exchanger, 32 First blower, 33 First outdoor communication port, 35 First Indoor door (blower switching device), 36 1st outdoor door, 39 1st water sensor (water detection device), 41 2nd heat exchanger, 42 2nd blower, 43 2nd outdoor communication port, 45 2nd indoor door ( Blower switching device), 46 2nd outdoor door, 49 2nd water sensor (water detection device), 51 air conditioning case, 61 indoor communication port, 90 control device, 232 blower, 233 1st outdoor communication port, 235 1st indoor door , 236 1st outdoor door, 237 1st indoor communication port, 238 1st downstream sensor, 243 2nd outdoor communication port, 245 2nd indoor door, 246 2nd outdoor door, 247 2nd indoor communication port, 248 2nd downstream Sensor, 271 upstream sensor, 325 four-way valve

Claims (8)

A refrigeration cycle device (10) having a compressor (11), a first heat exchanger (31), a second heat exchanger (41), and a decompression device (12).
An air conditioning case (51) that houses the first heat exchanger and the second heat exchanger inside, and
A first refrigerant mode in which the first heat exchanger functions as a condenser and the second heat exchanger functions as an evaporator, and a second heat exchanger in which the first heat exchanger functions as an evaporator. A refrigerant switching device (25, 325) that switches between the second refrigerant mode and the second refrigerant mode that functions as a condenser.
Blowers (32, 42, 232) that blow air inside the air conditioning case, and
An indoor communication port (61, 237, 247) provided in the air-conditioning case through which air sent out into the vehicle interior flows, and
An outdoor communication port (33, 43, 233, 243) provided in the air-conditioning case through which air sent out of the vehicle interior flows.
A blower switching device that switches between a first blower mode in which the wind that has passed through the first heat exchanger is passed through the indoor communication port and a second blower mode in which the wind that has passed through the second heat exchanger is flown through the indoor communication port. (35, 45, 235, 245) and
A water detection device (39, 49, 238, 248, 271) that detects condensed water generated in the first heat exchanger or the second heat exchanger.
When the amount of condensed water detected by the water detection device exceeds a predetermined amount, the refrigerant switching device is controlled to switch between the first refrigerant mode and the second refrigerant mode, and the blower switching device is used. A vehicle air conditioner including a control device (90) that controls and switches between the first blower mode and the second blower mode. The control device controls the refrigerant switching device to switch between the first refrigerant mode and the second refrigerant mode, and then controls the blower switching device to perform the first blower mode and the second blower mode. The vehicle air conditioner according to claim 1. The vehicle air conditioner according to claim 1 or 2, wherein the water detection device is a water sensor (39, 49). The vehicle air conditioner according to claim 1 or 2, wherein the control device estimates the amount of condensed water generated based on the output of the blower. The water detection device is
An upstream sensor (271) that measures the physical quantity of upstream air before heat exchange with the first heat exchanger or the second heat exchanger.
It is equipped with a downstream sensor (238, 248) that measures the physical quantity of the downstream air after heat exchange with the first heat exchanger or the second heat exchanger.
The vehicle air conditioner according to claim 1 or 2, wherein the control device estimates the amount of condensed water generated from the physical quantity of air measured by the upstream sensor and the downstream sensor. In the refrigerant switching device (325), before and after switching between the first refrigerant mode and the second refrigerant mode, the direction of the refrigerant flowing inside the first heat exchanger or the inside of the second heat exchanger is determined. The vehicle air conditioner according to any one of claims 1 to 5, wherein the flow of the refrigerant is switched so as not to change. The first outdoor door (36, 236) that adjusts the amount of wind that has passed through the first heat exchanger to the outdoor communication port, and
It is provided with a second outdoor door (46, 246) that adjusts the amount of wind that has passed through the second heat exchanger to flow through the outdoor communication port.
The blower switching device is
A first interior door (35, 235) that adjusts the amount of air that has passed through the first heat exchanger to flow into the indoor communication port, and
The vehicle according to any one of claims 1 to 6, further comprising a second interior door (45, 245) for adjusting the amount of wind that has passed through the second heat exchanger to flow through the indoor communication port. Air conditioner for. The vehicle air conditioner according to any one of claims 1 to 7, wherein the blower (232) is provided between the first heat exchanger and the second heat exchanger.

Images