JP7243197B2 - vehicle air conditioner - Google Patents

Description

The disclosure herein relates to vehicle air conditioners.

Patent Document 1 discloses a vehicle air conditioner in which a sub-condenser and a PTC heater are arranged in an air duct for air conditioning. The air flowing through the air conditioning air ducts is heated by sub-condensers that form part of the refrigeration cycle. Insufficient heating by the sub-condenser is compensated by heat generated by the PTC heater. The contents of the prior art documents cited as prior art are incorporated by reference as descriptions of technical elements in this specification.

JP 2010-143533 A

Prior art arrangements use a condenser and a heater to heat the gaseous air. For this reason, compared with the case where the object to be heated by the heater is a liquid, the efficiency of heat transfer from the heater to the object to be heated tends to be low. Therefore, it is necessary to increase the size of the heater in order to obtain the required heating capacity, and since a heater with a large size is used in addition to the condenser, the size of the vehicle air conditioner tends to increase. In view of the above, or in other aspects not mentioned, there is a need for further improvements in vehicle air conditioners.

One disclosed object is to provide a compact vehicle air conditioner.

The vehicle air conditioner disclosed herein includes a compressor (11) that compresses refrigerant, a condenser (12) that condenses the compressed refrigerant and heats conditioned air flowing in the vehicle interior, and a compressor (12) that heats the conditioned air flowing in the vehicle interior. An outdoor unit (25) that exchanges heat with the air of the air, an air conditioning flow path (10) that connects the compressor, the condenser, and the outdoor unit to form a refrigerant flow path in which the refrigerant circulates, and flows out of the condenser. and an electric heater (35, 335) that heats and evaporates the liquid-phase refrigerant flowing from the refrigerant to the compressor.
The air conditioning flow path includes an outdoor unit flow path (20), which is a refrigerant flow path in which the refrigerant circulates via the outdoor unit, and a bypass flow path (20), which is a refrigerant flow path in which the refrigerant circulates without passing through the outdoor unit. 30) and
Further, the vehicle air conditioner is provided in the air-conditioning flow path and has a first mode in which the refrigerant does not flow in the bypass flow path and a second mode in which the refrigerant flows in the bypass flow path. and a switching valve (31) for switching between and an air conditioning control unit (90) for controlling the switching valve and the electric heater,
The air conditioning control unit does not drive the electric heater in the first mode, and drives the electric heater to heat and evaporate the liquid-phase refrigerant in the second mode,
Furthermore, the vehicle air conditioner includes an outside air temperature sensor (92) that measures the temperature outside the vehicle, an outside air humidity sensor (95) that measures the humidity outside the vehicle, and an outdoor unit sensor (26) that measures the temperature of the outdoor unit. and
The air conditioning control unit calculates the dew point temperature from the outside air temperature measured by the outside air temperature sensor and the outside air humidity measured by the outside air humidity sensor. If the temperature of the outdoor unit measured by the outdoor unit sensor is less than the dew point temperature, the air conditioning operation is performed in the second mode.

According to the disclosed vehicle air conditioner, an electric heater is provided to heat and evaporate the liquid-phase refrigerant flowing from the condenser to the compressor. Therefore, even if sufficient heat cannot be obtained from the outside air in the outdoor unit, the heat of the electric heater can be used to evaporate the liquid-phase refrigerant. Therefore, the heating operation using the condenser as a heat source can be realized using the refrigeration cycle regardless of the temperature of the outdoor unit. Therefore, it is not necessary to provide a large-sized heater for heating the air, in addition to the electric heater for heating and evaporating the liquid-phase refrigerant. As described above, it is possible to provide a compact vehicle air conditioner that uses the condenser as a main heat source in heating operation.

The multiple aspects disclosed in this specification employ different technical means to achieve their respective objectives. Reference numerals in parentheses described in the claims and this section are intended to exemplify the correspondence with portions of the embodiments described later, and are not intended to limit the technical scope. Objects, features, and advantages disclosed in this specification will become clearer with reference to the following detailed description and accompanying drawings.

1 is a configuration diagram showing a configuration of a vehicle air conditioner; FIG. It is a block diagram about control of a vehicle air conditioner. 4 is a flowchart relating to control of a vehicle air conditioner; 1 is a configuration diagram showing the configuration of a vehicle air conditioner in a normal mode; FIG. 1 is a configuration diagram showing a configuration of a vehicle air conditioner in bypass mode; FIG. It is a flow chart about control of a vehicle air conditioner in a 2nd embodiment. It is a block diagram which shows the structure of the vehicle air conditioner in 3rd Embodiment.

A number of embodiments will be described with reference to the drawings. In several embodiments, functionally and/or structurally corresponding and/or related parts may be labeled with the same reference numerals or reference numerals differing by one hundred or more places. For corresponding and/or associated parts, reference can be made to the description of other embodiments.

1ST EMBODIMENT The vehicle air conditioner 1 is an air conditioner mounted in a vehicle. The vehicle is, for example, an automobile equipped with a gasoline-powered engine. However, as the vehicle, an electric vehicle equipped with a driving motor, a hybrid vehicle equipped with both an engine and a motor, or the like can be adopted. The vehicle air conditioner 1 includes a blower unit that blows air and an air conditioning unit that adjusts the air temperature. The vehicle air conditioner 1 is a device that adjusts the temperature and humidity of the air taken in and blows the air into the vehicle interior. In other words, the vehicle air conditioner 1 is a device that performs air conditioning operations such as a heating operation, a cooling operation, and a dehumidifying operation in the passenger compartment.

In FIG. 1 , a vehicle air conditioner 1 includes a compressor 11 , a condenser 12 , an evaporator 15 and an outdoor unit 25 . The vehicle air conditioner 1 includes an air conditioning flow path 10 that connects a compressor 11, a condenser 12, an evaporator 15, and an outdoor unit 25 and functions as a refrigerant flow path for circulating the refrigerant to each device.

The compressor 11 is a device that increases the pressure and temperature of the refrigerant by compressing the gas phase refrigerant. The condenser 12 is a device that radiates the heat of the vapor-phase refrigerant to the surroundings of the condenser 12 to condense the vapor-phase refrigerant into a liquid-phase refrigerant. The condenser 12 functions as a heating heat exchanger that heats the air-conditioned air by exchanging heat between the air-conditioned air flowing in the vehicle compartment and the refrigerant. The outdoor unit 25 is a heat exchanger that heat-exchanges the liquid-phase refrigerant with the outside air to bring the temperature of the refrigerant closer to the temperature of the outside air. The evaporator 15 is a device that applies heat around the evaporator 15 to the liquid-phase refrigerant to evaporate the liquid-phase refrigerant into a gas-phase refrigerant. The evaporator 15 functions as a cooling heat exchanger that exchanges heat between the air-conditioned air flowing in the vehicle interior and the refrigerant to cool the air-conditioned air. The vehicle air conditioner 1 configures a refrigeration cycle by annularly connecting a compressor 11, a condenser 12, an evaporator 15, and an outdoor unit 25 using an air conditioning flow path 10 and circulating a refrigerant through each device. are doing. In addition, the vehicle air conditioner 1 can function as a heat pump by utilizing the heat obtained from the outside air by the outdoor unit 25 for heating operation while forming a refrigerating cycle.

The vehicle air conditioner 1 includes a heating heater 9 . The heating heater 9 is a heating device that controls the amount of heat generated by the magnitude of the current flowing through the heating heater 9 . However, the heating heater 9 may be a combustion heater that burns fuel. The heating heater 9 is a device smaller in size than the condenser 12 . The heater 9 for heating is provided inside the air conditioning case through which the conditioned air flows. The condenser 12 is provided inside an air-conditioning case through which air-conditioning air flows. The heating heater 9 and the condenser 12 heat air to generate warm air for heating operation. The evaporator 15 is provided inside an air-conditioning case through which conditioned air flows. The evaporator 15 cools air to generate cool air for cooling operation.

The outdoor unit 25 has an outdoor unit sensor 26 . The outdoor unit sensor 26 has a temperature sensor that measures the surface temperature of the outdoor unit 25 . The outdoor unit sensor 26 may include a sensor other than the temperature sensor. For example, a weight sensor may be provided for measuring whether or not frost has formed on the surface of the outdoor unit 25 from changes in weight. Alternatively, an optical sensor may be provided for measuring whether or not the surface of the outdoor unit 25 is frosted from changes in reflected light or transmitted light.

The vehicle air conditioner 1 includes an accumulator 18 , an evaporator expansion valve 14 , and an outdoor unit expansion valve 24 . The accumulator 18 is connected to a suction pipe, which is a pipe located upstream of the compressor 11 . The accumulator 18 is a device that separates the liquid-phase refrigerant and the gas-phase refrigerant so that only the gas-phase refrigerant flows to the compressor 11 . The accumulator 18 prevents the liquid-phase refrigerant from flowing into the compressor 11 .

The evaporator expansion valve 14 is provided between the condenser 12 and the evaporator 15 in the air conditioning flow path 10 . The evaporator expansion valve 14 is a device that expands the liquid-phase refrigerant that has flowed out of the condenser 12 and causes it to flow out toward the evaporator 15 . By expanding the liquid-phase refrigerant in the evaporator expansion valve 14 , the liquid-phase refrigerant can be decompressed into a low-temperature, low-pressure liquid-phase refrigerant that is easily evaporated in the evaporator 15 . The evaporator expansion valve 14 is an electric expansion valve whose opening can be electrically adjusted using a motor. However, a mechanical expansion valve may be used as the evaporator expansion valve 14 .

The outdoor unit expansion valve 24 is provided between the condenser 12 and the outdoor unit 25 in the air conditioning flow path 10 . The outdoor unit expansion valve 24 is a device that expands the liquid-phase refrigerant that has flowed out of the condenser 12 and causes it to flow out toward the outdoor unit 25 . By expanding the liquid-phase refrigerant in the outdoor unit expansion valve 24 , the liquid-phase refrigerant can be decompressed into a low-temperature, low-pressure liquid-phase refrigerant that is easily evaporated in the outdoor unit 25 . The outdoor unit expansion valve 24 is an electric expansion valve whose opening can be electrically adjusted using a motor. However, a mechanical expansion valve may be used as the outdoor unit expansion valve 24 .

The vehicle air conditioner 1 includes an electric heater 35 . The electric heater 35 is provided along the refrigerant pipe forming the air conditioning flow path 10 . The electric heater 35 is a heating device that controls the amount of heat generated by the magnitude of the current flowing through the electric heater 35 . Therefore, the temperature of the electric heater 35 can be electrically controlled. As the electric heater 35, it is preferable to use a PTC heater which is an electric heater having a positive temperature coefficient. The PTC heater is a heater that has a characteristic that the more the temperature rises, the more difficult it is for current to flow, and the heater can easily maintain a predetermined temperature. Therefore, the temperature control of the PTC heater is easier than that of a heater, such as a nichrome wire heater, whose electric resistance value does not change significantly even when the temperature is changed.

The vehicle air conditioner 1 includes a heater expansion valve 34 . The heater expansion valve 34 is provided between the condenser 12 and the electric heater 35 in the air conditioning flow path 10 . The heater expansion valve 34 is a device that expands the liquid-phase refrigerant that has flowed out of the condenser 12 and causes it to flow out toward the electric heater 35 . By expanding the liquid-phase refrigerant in the heater expansion valve 34 , the liquid-phase refrigerant can be decompressed in the electric heater 35 to a low-temperature, low-pressure liquid-phase refrigerant that is easily evaporated. The heater expansion valve 34 is an electric expansion valve whose opening can be electrically adjusted using a motor. However, a mechanical expansion valve may be used as the heater expansion valve 34 .

The air-conditioning channel 10 includes an outdoor unit channel 20 and a bypass channel 30 . The outdoor unit flow path 20 is a flow path for circulating the refrigerant via the outdoor unit 25 . The outdoor unit flow path 20 is provided between the condenser 12 and the accumulator 18 in the air conditioning flow path 10 . The outdoor unit channel 20 is a channel for guiding the liquid-phase refrigerant that has flowed out of the condenser 12 to the outdoor unit 25 . The bypass channel 30 is a channel for circulating the refrigerant without passing through the outdoor unit 25 . The bypass flow path 30 is provided between the condenser 12 and the accumulator 18 in the air conditioning flow path 10 . The bypass channel 30 is a channel for guiding the liquid-phase refrigerant that has flowed out of the condenser 12 without passing through the outdoor unit 25 to the evaporator expansion valve 14 or the heater expansion valve 34 .

A switching valve 31 is provided in the bypass flow path 30 . The switching valve 31 is a valve device that opens and closes the refrigerant flow path between a state in which the refrigerant can pass through the bypass flow path 30 and a state in which the refrigerant cannot pass through the bypass flow path 30 . Refrigerant can pass through the bypass channel 30 when the switching valve 31 is open. The refrigerant cannot pass through the bypass channel 30 when the switching valve 31 is closed. The open state of the switching valve 31 includes a fully open state and a slightly open state. The fully open state of the switching valve 31 is a state in which the degree of opening of the bypass channel 30 is maximized. The slightly open state of the switching valve 31 is a state in which the degree of opening of the bypass passage 30 is made smaller than in the fully open state and larger than in the closed state.

Components other than the switching valve 31 are not provided in the bypass flow path 30 . On the other hand, the outdoor unit flow path 20 is provided with an outdoor unit expansion valve 24 and an outdoor unit 25 . Therefore, the outdoor unit flow path 20 is a refrigerant flow path with a large pressure loss compared to the bypass flow path 30 . Therefore, in the closed state of the switching valve 31, the refrigerant flows through the outdoor unit channel 20 through which the refrigerant can flow. On the other hand, in the open state of the switching valve 31 , the refrigerant preferentially flows through the bypass flow path 30 having a smaller pressure loss than the outdoor unit flow path 20 . Here, the state in which the switching valve 31 is closed and the refrigerant cannot flow through the bypass passage 30 is the first mode. On the other hand, the state in which the switching valve 31 is opened and the refrigerant can flow through the bypass passage 30 is the second mode.

In the first mode, all the refrigerant flows through the outdoor unit flow path 20 because the refrigerant cannot flow through the bypass flow path 30 . On the other hand, in the second mode, part of the refrigerant may flow through the outdoor unit channel 20 . Therefore, in the second mode, there are a case where no refrigerant flows through the outdoor unit flow path 20 and a case where a part of the refrigerant flows through the outdoor unit flow path 20 . In particular, when the switching valve 31 is fully open, the refrigerant flows only through the bypass channel 30 and does not flow through the outdoor unit channel 20 . On the other hand, when the switching valve 31 is in the slightly open state, the refrigerant flows through both the outdoor unit flow path 20 and the bypass flow path 30 .

A first confluence portion 10a, which is a confluence portion of the outdoor unit flow path 20 on the downstream side of the outdoor unit 25 and the bypass flow path 30 on the downstream side of the switching valve 31, includes the evaporator expansion valve 14 and the heater expansion valve. 34 is located upstream. In the outdoor unit flow path 20, a check valve 27 is provided between the outdoor unit 25 and the first confluence portion 10a. The check valve 27 is a valve device that controls the flow of refrigerant so that the refrigerant flows from the outdoor unit 25 toward the first junction portion 10a and does not flow from the first junction portion 10a toward the outdoor unit 25. be.

A second confluence portion 10b, which is a confluence portion of the outdoor unit flow path 20 on the downstream side of the outdoor unit 25 and the air conditioning flow path 10 on the upstream side of the accumulator 18, is downstream of the evaporator 15 and the electric heater 35. positioned. In the outdoor unit flow path 20, an on-off valve 28 is provided between the outdoor unit 25 and the second junction portion 10b. The on-off valve 28 is a valve device that switches between flowing the refrigerant that has flowed out of the outdoor unit 25 toward the first merging portion 10a or flowing toward the second merging portion 10b without passing through the first merging portion 10a. .

In the air-conditioning flow path 10 from the outdoor unit 25 to the accumulator 18, no parts other than the on-off valve 28 are provided in the refrigerant flow path that does not pass through the first junction portion 10a. On the other hand, an evaporator expansion valve 14 or a heater expansion valve 34 is provided in the refrigerant flow path passing through the first junction portion 10a in the air conditioning flow path 10 from the outdoor unit 25 to the accumulator 18 . Therefore, the refrigerant flow path passing through the first confluence portion 10a is a refrigerant flow path with a large pressure loss compared to the refrigerant flow path not passing through the first confluence portion 10a. Therefore, when the on-off valve 28 is closed, the refrigerant flows through the refrigerant channel via the first junction portion 10a through which the refrigerant can flow. On the other hand, when the on-off valve 28 is open, the refrigerant flows through the refrigerant flow path that does not pass through the first confluence portion 10a, which is a refrigerant flow path with a smaller pressure loss than the refrigerant flow path that passes through the first confluence portion 10a. .

FIG. 2 is a diagram showing a control system. A control unit (ECU) in this specification may also be called an electronic control unit. The controller is provided by (a) an algorithm as a plurality of logics called if-then-else form, or (b) a trained model tuned by machine learning, eg, an algorithm as a neural network.

The controller is provided by a control system including at least one computer. A control system may include multiple computers linked by data communication devices. A computer includes at least one hardware processor, which is a hardware processor. A hardware processor may be provided by (i), (ii), or (iii) below.

(i) the hardware processor may be at least one processor core executing a program stored in at least one memory; In this case, the computer is provided by at least one memory and at least one processor core. The processor core is called CPU: Central Processing Unit, GPU: Graphics Processing Unit, RISC-CPU, or the like. Memory is also called a storage medium. A memory is a non-transitory and tangible storage medium that non-temporarily stores "programs and/or data" readable by a processor. A storage medium is provided by a semiconductor memory, a magnetic disk, an optical disk, or the like. The program may be distributed alone or as a storage medium storing the program.

(ii) a hardware processor may be a hardware logic circuit; In this case, the computer is provided by digital circuits containing a large number of programmed logic units (gate circuits). A digital circuit is also called a logic circuit array, for example, ASIC: Application-Specific Integrated Circuit, FPGA: Field Programmable Gate Array, PGA: Programmable Gate Array, CPLD: Complex Programmable Logic Device. A digital circuit may include a memory that stores programs and/or data. Computers may be provided by analog circuits. Computers may be provided by a combination of digital and analog circuits.

(iii) The hardware processor may be a combination of (i) above and (ii) above. (i) and (ii) are located on different chips or on a common chip. In these cases, part (ii) is also called an accelerator.

Controllers, signal sources, and controlled objects provide a variety of elements. At least some of those elements may be referred to as blocks, modules, or sections. Moreover, the elements included in the control system are called functional means only if they are intentional.

The controls and techniques described in this disclosure may be implemented by a dedicated computer provided by configuring a processor and memory programmed to perform one or more functions embodied by the computer program. may Alternatively, the controls and techniques described in this disclosure may be implemented by a dedicated computer provided by configuring the processor with one or more dedicated hardware logic circuits. Alternatively, the controller and techniques described in this disclosure may be combined with a processor and memory programmed to perform one or more functions and a processor configured by one or more hardware logic circuits. may be implemented by one or more dedicated computers configured by The computer program may also be stored as computer-executable instructions on a computer-readable non-transitional tangible recording medium.

In FIG. 2 , an air conditioning control unit 90 is connected to an outdoor unit sensor 26 , an outside air temperature sensor 92 , an inside air temperature sensor 93 , a solar radiation sensor 94 , an outside air humidity sensor 95 and an air conditioning switch 96 . The outside air temperature sensor 92 is a temperature sensor that measures the temperature outside the passenger compartment. The inside air temperature sensor 93 is a temperature sensor that measures the temperature inside the vehicle. The solar radiation sensor 94 is a sensor that measures the solar radiation received by the vehicle. The air conditioning control unit 90 acquires information such as the outside air temperature measured by the outside air temperature sensor 92, the inside air temperature measured by the inside air temperature sensor 93, and the amount of solar radiation measured by the solar radiation amount sensor 94, and blows into the vehicle compartment. Then, the target blowout temperature, which is the target temperature of the conditioned air, is calculated.

The outside air humidity sensor 95 is a humidity sensor that measures the humidity outside the vehicle compartment. The air conditioning control unit 90 acquires information on the outside air humidity measured by the outside air humidity sensor 95, and performs dehumidifying operation, window fog prevention operation, and the like.

The air conditioning control unit 90 acquires information on the surface temperature of the outdoor unit 25 from the outdoor unit sensor 26 and determines whether or not the outdoor unit 25 can appropriately absorb heat from the surroundings of the outdoor unit 25 . Air conditioning control according to the temperature of the outdoor unit 25 will be described in detail later.

The air-conditioning switch 96 is a switch operated by a passenger, and includes a switch for switching ON/OFF of the air-conditioning operation, a switch for changing the set temperature and air volume, a switch for switching between the inside air mode and the outside air mode, and the like. . The air-conditioning switch 96 includes a switch for the passenger to select which of the blowout modes to use for the air-conditioning operation. However, when the air-conditioning operation is performed in the auto mode, the air-conditioning mode is not switched by the operation of the passenger, but is automatically switched. The air-conditioning control unit 90 performs air-conditioning operation based on air-conditioning settings such as temperature and air volume set by the passenger using the air-conditioning switch 96 .

The air conditioning control unit 90 is connected to the heating heater 9, the compressor 11, the evaporator expansion valve 14, the outdoor unit expansion valve 24, the on-off valve 28, the switching valve 31, the heater expansion valve 34, and the electric heater 35. there is The air conditioning control unit 90 controls the output of the heating heater 9 to adjust the temperature of the conditioned air. That is, the output of the heating heater 9 is increased as the target blowing temperature of the conditioned air is higher. For example, the temperature of the heating heater 9 is controlled within a temperature range of about 60°C to 80°C. The air conditioning control unit 90 controls the output of the compressor 11 to adjust the temperature of the conditioned air. That is, the greater the difference between the current temperature in the passenger compartment and the set temperature set by operating the air conditioning switch 96, the more the output of the compressor 11 is increased to increase the circulation amount of the refrigerant.

The air conditioning control unit 90 appropriately controls the opening degrees of the evaporator expansion valve 14, the outdoor unit expansion valve 24, and the heater expansion valve 34 to control how much the liquid-phase refrigerant is expanded. The air conditioning control unit 90 appropriately controls the opening and closing of the on-off valve 28 and the switching valve 31 to control the flow path through which the refrigerant flows. The air-conditioning control unit 90 controls the output of the electric heater 35 to adjust the heating amount of the liquid-phase refrigerant flowing through the air-conditioning flow path 10 .

Operation control in the heating operation of the vehicle air conditioner 1 will be described below. In FIG. 3, when the heating operation of the vehicle air conditioner 1 is started, the temperature of the outdoor unit 25 measured using the outdoor unit sensor 26 is acquired in step S101. Here, instead of measuring the temperature of the outdoor unit 25 using the outdoor unit sensor 26 , the temperature of the outdoor unit 25 may be estimated from the outside air temperature measured by the outside air temperature sensor 92 . After acquiring the temperature of the outdoor unit 25, the process proceeds to step S111.

In step S111, it is determined whether or not the acquired temperature of the outdoor unit 25 is lower than a predetermined temperature. Here, the predetermined temperature is a temperature at which the liquid-phase refrigerant can be heat-exchanged with the outside air in the outdoor unit 25 to evaporate the liquid-phase refrigerant. That is, the predetermined temperature is a temperature at which the compressor 11 can be stably driven without causing a liquid backflow phenomenon in which the liquid-phase refrigerant is sucked into the compressor 11 . The predetermined temperature is 5° C., for example.

The predetermined temperature is not limited to the temperature at which all of the liquid-phase refrigerant is evaporated into gas-phase refrigerant in the outdoor unit 25 . The predetermined temperature may be a temperature that does not cause frost formation in the outdoor unit 25 . That is, even if water such as condensed water adheres to the surface of the outdoor unit 25, the water does not stay in the solid state of ice on the surface of the outdoor unit 25 at this temperature. When frost forms on the surface of the outdoor unit 25, the fins forming the outdoor unit 25 are clogged, and heat cannot be exchanged properly. When the predetermined temperature is a temperature that does not cause frost formation in the outdoor unit 25, the predetermined temperature is 0°C, for example. When it is determined that the temperature of the outdoor unit 25 is lower than the predetermined temperature, it is determined that the operation of the refrigeration cycle using the outdoor unit 25 is not stable, and the process proceeds to step S130. On the other hand, when it is determined that the temperature of the outdoor unit 25 is equal to or higher than the predetermined temperature, it is determined that the operation of the refrigeration cycle using the outdoor unit 25 is stable, and the process proceeds to step S120.

In step S120, the operation of the vehicle air conditioner 1 is controlled in the normal mode. FIG. 4 is a diagram showing the flow of refrigerant in the normal mode. In this figure, the flow paths through which the coolant flows are indicated by solid lines, and the flow paths through which the coolant does not flow are indicated by dashed lines. In the normal mode, the on-off valve 28 is open. The switching valve 31 is in a closed state. The electric heater 35 is in a state where electricity is not flowing and no heat is generated. Normal mode provides an example of the first mode.

The high-temperature and high-pressure vapor-phase refrigerant compressed by the compressor 11 is condensed by the condenser 12 to become a liquid-phase refrigerant. Thereafter, the liquid-phase refrigerant flows through the outdoor unit flow path 20 and is expanded by the outdoor unit expansion valve 24 to become a low-temperature, low-pressure liquid-phase refrigerant. The low-temperature, low-pressure liquid-phase refrigerant is heated by the outside air in the outdoor unit 25 to evaporate and become a gas-phase refrigerant. The vapor-phase refrigerant passes through the accumulator 18 and is sucked into the compressor 11, where it is compressed again and circulated through the refrigeration cycle.

If the conditioned air cannot be heated to the target blowing temperature only by heating the conditioned air by the condenser 12, or if the temperature difference between the current inside air temperature and the set temperature is very large, the heater 9 for heating is also used. to heat the air-conditioning air. While maintaining the state of circulating the refrigerant in the normal mode, the process proceeds to step S141.

In step S130, the operation of the vehicle air conditioner 1 is controlled in the bypass mode. FIG. 5 is a diagram showing the flow of refrigerant in bypass mode. In this figure, the flow paths through which the coolant flows are indicated by solid lines, and the flow paths through which the coolant does not flow are indicated by dashed lines. In the bypass mode, the on-off valve 28 is closed. The switching valve 31 is in an open state. The electric heater 35 is in a state where electricity flows and heat is generated. Bypass mode provides an example of a second mode.

The vapor-phase refrigerant compressed by the compressor 11 is condensed by the condenser 12 to become a liquid-phase refrigerant. Thereafter, the liquid-phase refrigerant flows through the bypass passage 30 and is expanded by the heater expansion valve 34 to become a low-temperature, low-pressure liquid-phase refrigerant. The low-temperature, low-pressure liquid-phase refrigerant is heated by the electric heater 35 to evaporate and become a gas-phase refrigerant. The vapor-phase refrigerant passes through the accumulator 18 and is sucked into the compressor 11, where it is compressed again by the compressor 11 and circulates through the refrigeration cycle.

An example of refrigerant temperature change in the bypass mode will be described below. The vapor-phase refrigerant compressed by the compressor 11 rises in temperature to become a vapor-phase refrigerant of about 60°C. This vapor-phase refrigerant is condensed and sub-cooled by the condenser 12 to become a liquid-phase refrigerant of about 50°C. This liquid-phase refrigerant is expanded by the heater expansion valve 34 to lower its temperature and becomes a liquid-phase refrigerant of about 20°C. This liquid-phase refrigerant is heated by the electric heater 35 at about 40°C to evaporate, and becomes a gas-phase refrigerant while maintaining the temperature of about 20°C. This vapor-phase refrigerant is sucked into the compressor 11 and compressed to become a vapor-phase refrigerant of about 60° C. again, and circulates through the refrigeration cycle again.

The heat generated by the electric heater 35 acts on the liquid-phase refrigerant to evaporate the liquid-phase refrigerant into a gas-phase refrigerant. Therefore, the heat of the electric heater 35 can be applied to the liquid-phase refrigerant, which has a higher density than the gas-phase refrigerant. Therefore, the heat of the electric heater 35 can be easily applied to a larger amount of refrigerant. In addition, a large amount of heat including latent heat, which is the energy corresponding to the phase change from the liquid phase to the gas phase, can be applied to the refrigerant. Therefore, more heat from the electric heater 35 can be easily applied to the refrigerant.

By increasing the output of the compressor 11, the amount of refrigerant circulating in the air conditioning flow path 10 can be increased. As a result, the amount of refrigerant condensed in the condenser 12 can be increased, and the amount of heat released from the condenser 12 can be increased. When the output of the compressor 11 is increased, the output of the electric heater 35 is increased. Alternatively, by increasing the opening degree of the switching valve 31, the ratio of the refrigerant flowing through the outdoor unit channel 20 is reduced, and when the ratio of the refrigerant flowing through the bypass channel 30 is increased, the output of the electric heater 35 is increased. . In other words, the output of the electric heater 35 is increased as the amount of refrigerant flowing through the bypass passage 30 increases. As a result, the electric heater 35 appropriately evaporates the refrigerant according to the amount of refrigerant flowing through the bypass flow path 30, and the heating operation using the condenser 12 of the refrigeration cycle can be stably realized.

Switching of the output of the electric heater 35 is performed by increasing or decreasing the number of PTC heaters through which electric current flows in the electric heater 35 which is composed of a plurality of PTC heaters independent of each other. However, the electric heater 35 may be composed of a nichrome wire heater, and the output of the electric heater 35 may be switched by increasing or decreasing the current flowing through the nichrome wire.

If the conditioned air cannot be heated to the target blowing temperature by heating the condenser 12, or if the temperature difference between the current inside air temperature and the set temperature is very large, the heater 9 for heating is used in addition to the electric heater 35. heating operation. At this time, the temperature of the heating heater 9 is higher than the temperature of the electric heater 35 . That is, each output is controlled in a state where the energy consumed by the heating heater 9 for heating the conditioned air is greater than the energy consumed by the electric heater 35 for heating the liquid-phase refrigerant. The temperature of the electric heater 35 is, for example, 40.degree. C., and the temperature of the heating heater 9 is, for example, 70.degree. The state in which the refrigerant is circulated in the bypass mode is maintained, and the process proceeds to step S141.

In step S141, it is determined whether or not there is a request to end the air conditioning operation. A signal requesting the end of the air-conditioning operation is output when, for example, an occupant turns off an air-conditioning operation ON/OFF changeover switch. Alternatively, when the temperature measured by the inside air temperature sensor 93 is close to the set temperature and it can be determined that the air conditioning operation is completed, the air conditioning control unit 90 outputs a signal requesting the end of the air conditioning operation. Alternatively, when an ignition button mounted on the vehicle is turned off by a passenger's operation, a signal requesting termination of the air-conditioning operation is output. When there is a request to end the air-conditioning operation, the air-conditioning operation by the vehicle air conditioner 1 is ended. On the other hand, if there is no request to end the air-conditioning operation, the process returns to step S101 and repeats a series of controls to maintain the air-conditioning operation.

According to the embodiment described above, the vehicle air conditioner 1 includes the electric heater 35 that heats and evaporates the liquid-phase refrigerant that flows from the condenser 12 to the compressor 11 . Therefore, by evaporating the liquid-phase refrigerant by heating the electric heater 35, the vehicle air conditioner 1 can be configured so that the gas-phase refrigerant is sucked into the compressor 11 instead of the liquid-phase refrigerant. The electric heater 35 heats a liquid-phase refrigerant, not a gas such as air-conditioning air or gas-phase refrigerant. Therefore, the refrigerant with high density can be heated by the electric heater 35, and the heat of the electric heater 35 can be easily transferred to many refrigerants. In other words, the heat of the electric heater 35 can be utilized for the heating operation by utilizing the heat absorbing action of the refrigerant. Therefore, it is possible to provide the vehicle air conditioner 1 in which the heat transfer efficiency of the electric heater 35 used for the heating operation is improved.

Moreover, heating operation can be performed using the condenser 12 as a heat source in both the normal mode and the bypass mode. Therefore, a heat source for heating other than the condenser 12 can be easily omitted or downsized. Therefore, it is easy to reduce the size of the vehicle air conditioner 1 .

An electric heater 35 is used to heat the liquid phase refrigerant. Therefore, unlike the case where a combustion heater is used to heat the liquid-phase refrigerant, exhaust gas is not generated when the liquid-phase refrigerant is heated. Therefore, there is no need to provide a duct or the like for treating the exhaust gas, and it is easier to design the vehicle air conditioner 1 in a smaller size than when a combustion heater is used. Moreover, it is easy to increase the degree of freedom in designing the vehicle air conditioner 1 .

The air conditioning control unit 90 does not drive the electric heater 35 in the normal mode, and drives the electric heater 35 to evaporate the liquid-phase refrigerant in the bypass mode. Therefore, in the normal mode in which the outdoor unit 25 can heat and evaporate the liquid-phase refrigerant, the electric heater 35 does not consume electric power. Therefore, the power consumed by the electric heater 35 can be reduced compared to the case where the electric heater 35 is continuously driven regardless of the normal mode or the bypass mode.

In the normal mode, the on-off valve 28 may be closed and the refrigerant may flow through the heater expansion valve 34 and the electric heater 35 . According to this, even if only a part of the refrigerant evaporates in the outdoor unit 25 and the refrigerant flowing out from the outdoor unit 25 is a gas-liquid two-phase refrigerant in which the liquid-phase refrigerant and the gas-phase refrigerant are mixed, electricity The heater 35 can evaporate the liquid-phase refrigerant. Therefore, the refrigerating cycle can be stably operated by supplying the heat necessary for evaporating the refrigerant from the electric heater 35 to the extent that the heat obtained by the outdoor unit 25 alone is insufficient. Therefore, both the heat obtained from the outside air and the heat obtained from the electric heater 35 can be utilized for the heating operation.

The air conditioning control unit 90 performs air conditioning operation in normal mode when the temperature of the outdoor unit 25 is equal to or higher than a predetermined temperature, and performs air conditioning operation in bypass mode when the temperature of the outdoor unit 25 is lower than the predetermined temperature. In other words, if the temperature of the outdoor unit 25 is equal to or higher than a predetermined temperature, heat is obtained from the outside air to drive the refrigerating cycle, and if the temperature of the outdoor unit 25 is lower than the predetermined temperature, heat is obtained from the electric heater 35 to start the refrigerating cycle. drive. Therefore, even if the outdoor unit 25 cannot absorb the heat of evaporation of the refrigerant from the outside air, the refrigeration cycle can be driven to air-condition the vehicle interior. Therefore, the heating operation can be realized without relying on the heater 9 for heating even when the outside air temperature is low. Therefore, the heater 9 for heating can be omitted or miniaturized.

In the bypass mode, the refrigerant may be configured to flow only through the bypass flow path 30 of the two refrigerant flow paths, the outdoor unit flow path 20 and the bypass flow path 30 . According to this, the refrigerant flowing through the air-conditioning flow path 10 exchanges heat with the outside air in the outdoor unit 25, so that the heat of the refrigerant can be prevented from being radiated to the outside air. Therefore, it is possible to suppress the heat of the refrigerant from being lost to the outside, and reduce the electric power required by the electric heater 35 . Therefore, even in cold regions where the temperature of the outdoor unit 25 is extremely low, heating operation using the condenser 12 that constitutes the refrigeration cycle can be performed. In addition, even in the bypass mode, the pressure loss in the refrigerant flow path in the entire air conditioning flow path 10 can be reduced compared to the case where the refrigerant flows through the outdoor unit 25 . Therefore, the energy consumed by the compressor 11 can be reduced.

In the bypass mode, the output of the electric heater 35 is increased as the amount of liquid-phase refrigerant flowing through the bypass flow path 30 increases. Therefore, it is easy to prevent a situation in which the electric heater 35 lacks the heat necessary for evaporating the liquid-phase refrigerant. Moreover, compared with the case where the output of the electric heater 35 is always constant, the electric power consumed by the electric heater 35 can be easily reduced.

A heater expansion valve 34 for expanding the liquid-phase refrigerant is provided in the refrigerant flow path from the condenser 12 to the electric heater 35 . Therefore, the liquid-phase refrigerant can be evaporated at a lower temperature than when the heater expansion valve 34 is not provided. Therefore, the electric heater 35 cannot properly evaporate the liquid-phase refrigerant, and it is easy to suppress the occurrence of a liquid backflow phenomenon in which the liquid-phase refrigerant is sucked into the compressor 11 . Therefore, it is easy to reduce the power consumed by the electric heater 35 .

In the bypass mode, the air conditioning control unit 90 controls the temperature of the electric heater 35 that heats the liquid-phase refrigerant to be lower than the temperature of the heating heater 9 that heats the conditioned air. Therefore, the temperature difference between the electric heater 35 and the air around the electric heater 35 can be reduced. Therefore, of the heat generated by the electric heater 35, the heat lost by heating the air around the electric heater 35 can be reduced. Therefore, the heat generated by the electric heater 35 can be efficiently used to evaporate the liquid-phase refrigerant.

The electric heater 35 heats the refrigerant pipe of the air conditioning flow path 10 . Therefore, compared to the case of heating the refrigerant inside the outdoor unit 25 using a defrosting heater that warms the entire outdoor unit 25, it is easy to reduce the proportion of heat used for heating other than the refrigerant among the generated heat. In other words, a defrosting heater that needs to heat the entire large-sized outdoor unit 25 needs to transfer heat over a wide area of the outdoor unit 25, and much heat is transferred to and lost to members around the outdoor unit 25. Prone. On the other hand, the electric heater 35, which evaporates the liquid-phase refrigerant into the gas-phase refrigerant, only needs to heat a part of the refrigerant pipe, and it is easy to reduce heat transferred to members other than the refrigerant pipe to be heated. By covering the outer circumference of the refrigerant pipe to be heated together with the electric heater 35 with a heat insulating material or the like, it is possible to further reduce the amount of heat transmitted to members other than the object to be heated.

Second Embodiment This embodiment is a modification based on the preceding embodiment. In this embodiment, the dew point temperature is calculated and the operation mode of the vehicle air conditioner 1 is controlled based on the calculated dew point temperature.

Regarding the operation control in the heating operation of the vehicle air conditioner 1, portions different from the above-described embodiment will be described below. In FIG. 6, when the heating operation of the vehicle air conditioner 1 is started, the temperature of the outdoor unit 25 measured using the outdoor unit sensor 26 is acquired in step S101. Instead of measuring the temperature of the outdoor unit 25 using the outdoor unit sensor 26, the temperature of the outdoor unit 25 may be estimated from the outside air temperature measured by the outside air temperature sensor 92, or the like. After acquiring the temperature of the outdoor unit 25, the process proceeds to step S202.

In step S202, the outside air temperature measured using the outside air temperature sensor 92 is obtained. Here, when a plurality of outside air temperature sensors 92 are provided in the vehicle, the average value of the plurality of outside air temperature sensors 92 may be used as the outside air temperature. After acquiring the outside air temperature, the process proceeds to step S203, and the outside air humidity measured using the outside air humidity sensor 95 is acquired. After obtaining the outside air humidity, the process proceeds to step S204.

In step S204, the dew point temperature of the air around the vehicle is calculated. The dew point temperature is the temperature at which dew condensation occurs when air containing water vapor is cooled. Therefore, when the surface temperature of the outdoor unit 25 is cooled to a temperature lower than the dew point temperature, water vapor contained in the air around the vehicle adheres to the surface of the outdoor unit 25 as dew. The dew point temperature of the air around the vehicle can be calculated by calculating the water vapor pressure from the outside air temperature and the outside air humidity, and obtaining the temperature at which the calculated water vapor pressure becomes the saturated water vapor pressure. After calculating the dew point temperature, the process proceeds to step S211.

In step S211, it is determined whether or not the temperature of the outdoor unit 25 is below the dew point temperature. If the temperature of the outdoor unit 25 is less than the dew point temperature, it is judged that the temperature of the outdoor unit 25 is low and there is a possibility that the liquid phase refrigerant cannot be properly evaporated in the outdoor unit 25, and the process proceeds to step S130. That is, the vehicle air conditioner 1 is controlled in the bypass mode. On the other hand, when the temperature of the outdoor unit 25 is equal to or higher than the dew point temperature, the temperature of the outdoor unit 25 is high and condensation does not occur on the surface of the outdoor unit 25 . Therefore, it is determined that the liquid-phase refrigerant can be properly evaporated in the outdoor unit 25, and the process proceeds to step S120. That is, the vehicle air conditioner 1 is controlled in the normal mode in which efficient heating operation using a heat pump is performed.

When dew condensation occurs on the surface of the outdoor unit 25, in the outdoor unit 25, heat is exchanged between the refrigerant and the outside air via the condensed water. Therefore, the heat of the outside air is less likely to be transferred to the refrigerant, and the liquid-phase refrigerant is less likely to evaporate. Therefore, it is very important to use dew point temperature information to determine whether efficient heating operation using a heat pump is possible.

According to the embodiment described above, if the temperature of the outdoor unit 25 is equal to or higher than the dew point temperature, the air conditioning operation is performed in the normal mode, and if the temperature of the outdoor unit 25 is lower than the dew point temperature, the air conditioning operation is performed in the bypass mode. Therefore, based on the temperature and the dew point temperature of the outdoor unit 25, efficient heating operation using the heat pump in the normal mode and heating operation using the refrigeration cycle in the bypass mode can be appropriately used. . Therefore, it is possible to accurately determine whether or not efficient heating operation can be performed using the outdoor unit 25, and switch between the normal mode and the bypass mode.

Third Embodiment This embodiment is a modification based on the preceding embodiment. In this embodiment, a battery flow path 350 is provided for adjusting the temperature of the secondary battery 355, and the heat of the electric heater 335 provided in the battery flow path 350 is used in the bypass mode to evaporate the liquid phase refrigerant. I am letting

In FIG. 7 , the vehicle air conditioner 1 includes an electric heater 335 , a pump 351 , an inter-channel heat exchanger 352 , a battery heat exchanger 354 and a secondary battery 355 . The vehicle air conditioner 1 includes a battery flow path 350 that functions as a heat medium flow path that connects a pump 351, an inter-flow heat exchanger 352, and a battery heat exchanger 354 and circulates the heat medium in each device. I have. A heat medium is a fluid with a large heat capacity. The heat transfer medium is preferably a material in which a change in temperature causes a phase change between liquid and gas phases. As a heat medium, an antifreeze solution that suppresses freezing in cold regions may be used. Alternatively, a gas such as air may be used as the heat medium.

The pump 351 is a fluid transportation device for circulating the heat medium in the battery flow path 350 . The pump 351 is a device capable of circulating the gas-liquid two-phase heat medium in the battery flow path 350 . However, the heat medium in a completely gaseous state or a completely liquid state may be circulated in the battery flow path 350 .

The inter-channel heat exchanger 352 is a heat exchanger for exchanging heat between the refrigerant flowing through the air-conditioning channel 10 and the heat medium flowing through the battery channel 350 . The inter-channel heat exchanger 352 is provided across both the air-conditioning channel 10 and the battery channel 350 . The battery heat exchanger 354 is a heat exchanger for exchanging heat between the secondary battery 355 and the heat medium flowing through the battery flow path 350 . The secondary battery 355 is a device for storing electric power for rotating a driving motor, which is a driving source for driving the vehicle, and for supplying electric power to the driving motor. The secondary battery 355 is a heat-generating component that includes a battery stack formed by stacking a plurality of battery cells, a battery management unit that manages the amount of electricity stored in the battery cells, and the like. The secondary battery 355 is a component to be cooled that requires cooling because it generates heat during charging and discharging. In addition, the secondary battery 355 is a heating target component that requires heating because its performance deteriorates in a low-temperature environment. In other words, the secondary battery 355 is a temperature-controlled component whose temperature must be controlled within an appropriate temperature range.

The electric heater 335 is a heating device that heats the heat medium flowing through the battery flow path 350 . The electric heater 335 is a heating device that controls the amount of heat generated by the magnitude of the current flowing through the electric heater 335 . Therefore, the temperature of the electric heater 335 can be electrically controlled. As the electric heater 335, it is preferable to use a PTC heater which is an electric heater having a positive temperature coefficient.

The flow of the heat medium in the battery flow path 350 will be described below. The heat medium sent from the pump 351 exchanges heat with the secondary battery 355 in the battery heat exchanger 354 . At this time, if the temperature of the secondary battery 355 is higher than the temperature of the heat medium, the secondary battery 355 is cooled by the heat medium, and part of the heat medium heated by the secondary battery 355 It evaporates and the proportion of the gas phase state increases.

The battery heat exchanger 354 adjusts the temperature of the secondary battery 355 so that it falls within an appropriate temperature range. That is, in a state where the temperature of the secondary battery 355 is low, such as immediately after the start of operation of the vehicle, the secondary battery 355 is heated using the heat medium. On the other hand, when the temperature of the secondary battery 355 is high, such as when a sufficient amount of time has passed since the vehicle started operating, the secondary battery 355 is cooled using the heat medium.

The heat medium that has flowed through the battery heat exchanger 354 is heated by the electric heater 335 . Heating by the electric heater 335 increases the ratio of the gas phase state in the heat medium. Here, the electric heater 335 heats the heat medium by the heat medium by the secondary battery 355 via the battery heat exchanger 354, and heats the heat medium by an insufficient amount. This brings the heat medium into a state of having sufficient heat. When the heat medium is sufficiently heated by the heat of the secondary battery 355 in the battery heat exchanger 354, the heating by the electric heater 335 may not be performed.

The heat medium heated by the electric heater 335 exchanges heat with the refrigerant flowing through the air conditioning flow path 10 in the inter-flow path heat exchanger 352 . At this time, when the temperature of the refrigerant flowing through the air-conditioning flow path 10 is lower than the temperature of the heat medium flowing through the battery flow path 350, the heat medium heats the refrigerant and cools the heat generated by the refrigerant. Part of the medium will condense and the proportion in the liquid state will increase. The heat medium that has exchanged heat with the refrigerant flowing through the air conditioning flow path 10 in the inter-flow heat exchanger 352 is sucked into the pump 351 and circulates through the battery flow path 350 again.

An example of heat exchange in the inter-channel heat exchanger 352 will be described. In the inter-channel heat exchanger 352, the temperature of the refrigerant flowing through the air-conditioning channel 10 is, for example, 20°C. On the other hand, the temperature of the heat medium flowing through the battery flow path 350 is, for example, 50.degree. In this case, the coolant flowing through the air conditioning flow path 10 is heated by the heat medium flowing through the battery flow path 350 . That is, the refrigerant evaporates from the liquid phase to the gas phase by heat exchange between the refrigerant and the heat medium. Therefore, in the vehicle air conditioner 1 in the bypass mode, the refrigerant can be evaporated using the heat obtained in the inter-channel heat exchanger 352 . On the other hand, the heat medium flowing through the battery flow path 350 is cooled by the refrigerant flowing through the air conditioning flow path 10 . That is, the proportion of the liquid phase in the heat medium flowing through the battery flow path 350 increases.

In the bypass mode, when the refrigerant flowing through the air conditioning flow path 10 cannot be properly evaporated, the output of the electric heater 335 is increased. As a result, the energy of the heat medium flowing through the battery flow path 350 is increased, and the refrigerant flowing through the air conditioning flow path 10 is appropriately evaporated. That is, the electric heater 335 indirectly controls the evaporation of the liquid-phase refrigerant flowing through the air conditioning flow path 10 via the inter-flow heat exchanger 352 .

When the secondary battery 355 needs to be cooled, the heat medium cooled by the inter-flow heat exchanger 352 is not heated by the electric heater 335 to keep the temperature of the heat medium low. Thereby, the secondary battery 355 can be efficiently cooled. When the secondary battery 355 needs to be heated, the heat medium cooled by the inter-flow heat exchanger 352 is heated by the electric heater 335 to raise the temperature of the heat medium. Thereby, the secondary battery 355 can be heated. The temperature of the heat medium is maintained within an appropriate temperature range by cooling in the heat exchanger 352 between flow paths and heating by the electric heater 335 .

Further, when the refrigerant flowing through the air conditioning flow path 10 does not pass through the inter-flow heat exchanger 352, such as when the bypass mode is not set, the heat medium flowing through the battery flow path 350 is not actively cooled. Therefore, heat is released into the air while the heat medium circulates through the battery flow path 350 . Therefore, the temperature of the heat medium is maintained within an appropriate temperature range by cooling by releasing heat into the air and heating by the electric heater 335 .

According to the embodiment described above, the electric heater 335 heats the refrigerant flowing through the air conditioning flow path 10 via the inter-flow heat exchanger 352 . Therefore, even when the temperature of the outdoor unit 25 is low and the heating operation cannot be performed using the vehicle air conditioner 1 as a heat pump, the refrigerant is appropriately circulated to perform the heating operation using the condenser 12 as a heat source. It can be performed. Therefore, the heat source for the heating operation other than the condenser 12, such as the heater 9 for heating, can be omitted or reduced in size. Also, the electric heater 335 has two functions: a temperature control function for the secondary battery 355 and a refrigerant evaporation function in heating operation. Therefore, compared with the case where a heater is provided for each of a plurality of functions, it is easier to downsize the vehicle air conditioner 1 .

Other Embodiments The disclosures in this specification, drawings, etc. are not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations thereon by those skilled in the art. For example, the disclosure is not limited to the combinations of parts and/or elements shown in the embodiments. The disclosure can be implemented in various combinations. The disclosure can have additional parts that can be added to the embodiments. The disclosure encompasses omitting parts and/or elements of the embodiments. The disclosure encompasses permutations or combinations of parts and/or elements between one embodiment and another. The disclosed technical scope is not limited to the description of the embodiments. The disclosed technical scope is indicated by the description of the claims, and should be understood to include all changes within the meaning and range of equivalents to the description of the claims.

1 Vehicle Air Conditioner 9 Heater for Heating 10 Air Conditioning Channel 11 Compressor 12 Condenser 14 Evaporator Expansion Valve 15 Evaporator 18 Accumulator 20 Outdoor Unit Channel 24 Outdoor Unit Expansion valve 25 outdoor unit 26 outdoor unit sensor 28 opening/closing valve 30 bypass flow path 31 switching valve 34 expansion valve for heater 35 electric heater 90 air conditioning controller 92 outside air temperature sensor 93 inside air temperature sensor 95 Outside Air Humidity Sensor 335 Electric Heater 350 Battery Channel 351 Pump 352 Inter-Channel Heat Exchanger 354 Battery Heat Exchanger 355 Secondary Battery

Claims (5)

a compressor (11) for compressing a refrigerant;
a condenser (12) for condensing the compressed refrigerant and heating the conditioned air flowing in the vehicle compartment;
an outdoor unit (25) for exchanging heat between the refrigerant and the air outside the vehicle;
an air-conditioning flow path (10) connecting the compressor, the condenser, and the outdoor unit to form a refrigerant flow path through which a refrigerant circulates;
an electric heater (35, 335) that heats and evaporates a liquid-phase refrigerant that flows from the condenser to the compressor ;
The air-conditioning flow path is
an outdoor unit channel (20), which is a coolant channel through which coolant circulates through the outdoor unit;
A bypass flow path (30), which is a refrigerant flow path through which the refrigerant circulates without passing through the outdoor unit,
Further, the vehicle air conditioner is provided in the air-conditioning flow path and has a first mode in which the refrigerant does not flow in the bypass flow path and a second mode in which the refrigerant flows in the bypass flow path. A switching valve (31) for switching the flow state of
An air conditioning control unit (90) that controls the switching valve and the electric heater,
The air conditioning control unit does not drive the electric heater in the first mode, and drives the electric heater to heat and evaporate the liquid-phase refrigerant in the second mode,
Furthermore, the vehicle air conditioner includes an outside air temperature sensor (92) that measures the air temperature outside the vehicle,
an outside air humidity sensor (95) that measures the humidity outside the vehicle;
An outdoor unit sensor (26) that measures the temperature of the outdoor unit,
The air conditioning control unit calculates a dew point temperature from the outside air temperature measured by the outside air temperature sensor and the outside air humidity measured by the outside air humidity sensor, and the temperature of the outdoor unit measured by the outdoor unit sensor is equal to or higher than the dew point temperature. Then, the vehicle air conditioner performs the air conditioning operation in the first mode, and performs the air conditioning operation in the second mode if the temperature of the outdoor unit measured by the outdoor unit sensor is less than the dew point temperature. The vehicle air conditioner according to claim 1, wherein in the second mode, the air conditioning control unit increases the output of the electric heater as the amount of liquid-phase refrigerant flowing through the bypass flow path increases. 3. The air conditioner according to claim 1, further comprising a heater expansion valve (34) provided in a refrigerant flow path from the condenser to the electric heater in the air conditioning flow path to expand a liquid-phase refrigerant. air conditioner for vehicles. Equipped with a heating heater (9) that heats air-conditioned air flowing in the vehicle interior,
The air-conditioning control unit controls, in the second mode, the temperature of the electric heater that heats the liquid-phase refrigerant to be lower than the temperature of the heating heater that heats the conditioned air. 4. The vehicle air conditioner according to 3 . a secondary battery (355) for powering the vehicle;
a pump (351) for circulating the heat medium;
a battery heat exchanger (354) for exchanging heat between the secondary battery and a heat medium;
a battery flow path (350) connecting the pump and the battery heat exchanger to form a flow path through which a heat medium circulates;
an inter-channel heat exchanger (352) for exchanging heat between the heat medium flowing in the battery channel and the refrigerant flowing in the air conditioning channel;
The electric heater (335) heats the heat medium flowing through the battery flow path, thereby heating and evaporating the liquid-phase refrigerant flowing through the air conditioning flow path via the inter-flow heat exchanger. The vehicle air conditioner according to any one of claims 1 to 4.

Images