JP2018020646A - Air conditioning controller and air conditioning control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid a situation in which great time and effort are required for inspection and repair of an air condition even in a case where a battery is cooled using a heat pump of an air conditioner.SOLUTION: To cool a battery using a heat pump of an air conditioner, it is determined whether an operating state of the air conditioner meets a predetermined condition or not when cooling of the battery is started. If the state meets the predetermined condition, the occurrence of the cooling of the battery is stored. By so doing, even in a case where inspection and repair are required for an abnormal state in the air conditioner, a determination can be made whether the inspection and repair are caused by the occurrence of the cooling of the battery or not, by checking whether the occurrence of the cooling of battery is stored or not. This makes it possible to avoid a situation in which the cause of the abnormality cannot be specified, requiring great time and effort for the inspection and repair.SELECTED DRAWING: Figure 11

Description

  The present invention relates to a technique for cooling a secondary battery using a heat pump for air conditioning a vehicle interior.

  Vehicles equipped with large-capacity secondary batteries such as electric vehicles and hybrid vehicles have been developed. Generally, a secondary battery has an operating temperature range suitable for discharging or charging, and if the battery is discharged or charged outside the appropriate operating temperature range, the life of the secondary battery is shortened. Therefore, by monitoring the battery temperature of the secondary battery, if the battery temperature is too low, the secondary battery is heated, and conversely, if the temperature is too high, the secondary battery is cooled. Has been done to keep it in the proper operating temperature range.

Here, since the upper limit temperature of the appropriate operating temperature range is relatively low, it is difficult to cool the battery temperature below the upper limit temperature in cooling using cooling water and a radiator such as an engine. For this reason, a so-called heat pump is used for cooling the secondary battery.
In addition, mounting a dedicated heat pump to cool the secondary battery causes problems from the viewpoint of mounting space and manufacturing cost, so the heat pump mounted for cooling the interior of the passenger compartment can be It is also used for cooling (for example, Patent Document 1).

JP 2013-189118 A

  However, if cooling of the secondary battery is started during the air conditioning in the passenger compartment, the air conditioning may not be performed as usual. There was a problem that a great deal of labor was required for inspection and repair without being identified.

  The present invention has been made in view of the above-mentioned problems of the prior art, and avoids a situation in which a great deal of labor is required for the inspection and repair of the air conditioner even when the secondary battery is cooled using the heat pump of the air conditioner. The aim is to provide possible technology.

In order to solve the above-described problems, in the air conditioning control device and the air conditioning control method of the present invention, the secondary battery is cooled using a heat pump of an air conditioning device that air-conditions the passenger compartment. When battery cooling is performed, it is determined whether or not the operation state of the air conditioner satisfies a predetermined condition. If the predetermined condition is satisfied, the occurrence of battery cooling is stored.
In this way, even if inspection / repair is brought in as an abnormality of the air conditioner, the cause of being brought into inspection / repair is due to the occurrence of battery cooling. It can be determined whether or not. As a result, it is possible to avoid a situation where the cause of the abnormality cannot be identified and a great deal of labor is required for inspection and repair.

It is explanatory drawing which shows the rough structure of the air conditioning system 1 provided with the air-conditioning control apparatus 100 of a present Example. It is the block diagram which showed the internal structure of the air-conditioning control apparatus 100 of a present Example. It is a flowchart of the first half part of the air-conditioning control process which the air-conditioning control apparatus 100 of a present Example performs. It is a flowchart of the latter half part of the air-conditioning control process of a present Example. It is explanatory drawing which shows operation | movement of the air conditioning system 1 in air_conditionaing | cooling operation. It is explanatory drawing which shows operation | movement of the air conditioning system 1 in heating operation. It is a flowchart of the first half part of the battery cooling process performed in an air conditioning control process. It is a flowchart of the latter half part of a battery cooling process. It is explanatory drawing which shows the operation | movement in the case of performing battery cooling during heating operation. It is explanatory drawing which shows operation | movement in the case of performing battery cooling during air_conditionaing | cooling operation. It is explanatory drawing which illustrated the cooling conditions of the secondary battery 50 which the air-conditioning control apparatus 100 collects. It is the block diagram which showed the internal structure of the air-conditioning control apparatus 150 of the modification. 6 is an explanatory diagram illustrating a screen for informing the start of battery cooling displayed on the touch panel 2. FIG. It is a flowchart of the first half part of the battery cooling process of a modification. It is a flowchart of the second half part of the battery cooling process of a modification.

Hereinafter, examples will be described in order to clarify the contents of the present invention described above.
A. Device configuration :
FIG. 1 shows a rough configuration of an air conditioning system 1 including an air conditioning control device 100 of the present embodiment. As illustrated, the air conditioning system 1 includes an air conditioner 10 for air-conditioning a vehicle interior (not shown), a battery cooling device 40 for cooling a secondary battery 50 mounted on the vehicle (not shown), and an air conditioner. 10 and an air conditioning control device 100 that controls the operation of the battery cooling device 40.

The air conditioner 10 includes an electric compressor 11 that compresses refrigerant gas, an indoor condenser 12, a cooling two-way valve 13, a first expansion valve 14, an outdoor condenser 15, a second expansion valve 16, and three-way A valve 17, an evaporator 18, an accumulator 19, and a refrigerant pipe connecting them are provided. The electric compressor 11 of this embodiment corresponds to the “compressor” of the present invention.
Among these, the indoor condenser 12, the outdoor condenser 15, and the evaporator 18 are a kind of heat exchanger that exchanges heat between the refrigerant gas and the air, and are mounted in the air passage 20 that blows air into the vehicle interior. Has been.
The first expansion valve 14 and the second expansion valve 16 are fixed throttles, and decompression expansion is performed when the refrigerant gas compressed by the electric compressor 11 passes through the first expansion valve 14 or the second expansion valve 16. As a result, the temperature of the refrigerant gas decreases.

The cooling two-way valve 13 and the three-way valve 17 have a function of switching a path through which the refrigerant gas compressed by the electric compressor 11 flows.
For example, when the cooling two-way valve 13 is closed, the refrigerant gas passes through the first expansion valve 14 that is a fixed throttle. In contrast, when the cooling two-way valve 13 is opened, the refrigerant gas passes through the cooling two-way valve 13 without passing through the first expansion valve 14 having a high passage resistance.
Further, by switching the three-way valve 17, the refrigerant gas flows into the accumulator 19 from the three-way valve 17 through the evaporator 18, and flows into the accumulator 19 from the three-way valve 17 without going through the evaporator 18. The route to be switched can be switched.

In the accumulator 19, the liquid phase part contained in the flowing refrigerant gas is separated, and the gas-phase refrigerant gas is supplied to the electric compressor 11.
A pressure sensor 11 s is attached to the refrigerant pipe on the downstream side of the electric compressor 11, detects the pressure of the refrigerant gas compressed by the electric compressor 11 (hereinafter referred to as refrigerant pressure), and outputs it to the air conditioning control device 100. . Further, a temperature sensor 18 s is attached to the evaporator 18, and the temperature of the evaporator 18 (hereinafter referred to as “evaporator temperature”) is detected and output to the air conditioning control device 100.

The air conditioner 10 is also provided with a blower 21 and an air mixing plate 22. The blower 21 is mounted on the upstream side of the evaporator 18 in the blower passage 20, and blows air toward the evaporator 18 by rotating under the control of the air conditioning control device 100.
The air mixing plate 22 is mounted at a position downstream of the evaporator 18 in the air passage 20 and upstream of the indoor condenser 12, and the position can be adjusted. The air conditioning control device 100 controls the position of the air mixing plate 22 to adjust the amount of inflow of air that has passed through the evaporator 18 into the indoor condenser 12.

The battery cooling device 40 of the present embodiment has a function of cooling a secondary battery 50 mounted on a vehicle (not shown), a battery cooling heat exchanger 41, a battery cooling two-way valve 42, a cooling A water pump 43 is provided.
The battery cooling two-way valve 42 is connected to a battery cooling refrigerant pipe 44 that is branched out from the refrigerant pipe connecting the three-way valve 17 and the evaporator 18 of the air conditioner 10 described above. The battery cooling refrigerant pipe 44 on the downstream side of the battery cooling two-way valve 42 passes between the evaporator 18 of the air conditioner 10 and the accumulator 19 via the battery cooling heat exchanger 41. It merges with the refrigerant piping. Accordingly, when the battery cooling two-way valve 42 is opened, the refrigerant gas flowing between the three-way valve 17 and the evaporator 18 of the air conditioner 10 is diverted to the battery cooling refrigerant pipe 44, and the battery cooling heat is supplied. After passing through the exchanger 41, the refrigerant returns to the refrigerant pipe between the evaporator 18 and the accumulator 19.

The cooling water pump 43 is connected to a cooling water pipe 45 for cooling the secondary battery 50, and the cooling water pipe 45 on the downstream side of the cooling water pump 43 passes through the battery cooling heat exchanger 41. A secondary battery 50 is connected. Therefore, when the air conditioning control device 100 drives the cooling water pump 43, the cooling water circulates between the secondary battery 50 and the battery cooling heat exchanger 41 via the cooling water pipe 45.
At this time, the coolant gas flowing through the battery cooling refrigerant pipe 44 and the cooling water flowing through the cooling water pipe 45 are heat-exchanged by the battery cooling heat exchanger 41, whereby the cooling water is cooled. The secondary battery 50 is cooled by refluxing.
The secondary battery 50 is equipped with a battery temperature sensor 50 s that detects the battery temperature, and the battery temperature detected by the battery temperature sensor 50 s is output to the air conditioning controller 100.

A pressure sensor 11s, a temperature sensor 18s, and a battery temperature sensor 50s are connected to the air conditioning control device 100. The refrigerant pressure is transmitted from the pressure sensor 11s, the evaporator temperature is transmitted from the temperature sensor 18s, and the battery temperature sensor 50s is mounted. The battery temperature is input from. In addition, a touch panel 2 that is operated by a vehicle occupant (not shown) is also connected to the air conditioning control device 100. When the occupant operates the touch panel 2, either the cooling operation or the heating operation is performed on the air conditioning control device 100. It is possible to set the air conditioning operation or set the target temperature of the air conditioning.
The air-conditioning control device 100 is connected to various sensors, which will be described later, and based on the output of these sensors, the electric compressor 11, the cooling two-way valve 13, the three-way valve 17, the blower 21, and the air mixture By controlling the operation of the plate 22, the passenger compartment is air-conditioned.
Further, when it is determined that the battery cooling of the secondary battery 50 is necessary, the battery cooling is performed by controlling the battery cooling two-way valve 42 and the cooling water pump 43. This point will be described in detail later.

FIG. 2 shows a rough internal structure of the air-conditioning control apparatus 100 of the present embodiment. As shown in the figure, the air conditioning control device 100 of this embodiment includes an air conditioning operation acquisition unit 101, a target temperature acquisition unit 102, an indoor temperature acquisition unit 103, an outdoor temperature acquisition unit 104, a solar radiation amount acquisition unit 105, An operation state control unit 106, a battery temperature acquisition unit 107, a cooling necessity determination unit 108, a battery cooling unit 109, a travel state acquisition unit 110, a cooling condition collection unit 111, and a cooling generation storage unit 112 are provided. ing.
Note that these “parts” are abstract concepts in which the interior of the air conditioning control device 100 is classified for convenience, focusing on the functions of the air conditioning control device 100 for air conditioning and battery cooling in the vehicle interior. is there. Therefore, it does not indicate that the air conditioning control device 100 is physically divided into these “parts”. These “units” can be realized as a computer program executed by the CPU, can be realized as an electronic circuit including an LSI or a memory, or can be realized by combining them. . In this embodiment, the air conditioning control device 100 is mainly formed by a microcomputer having a CPU, a ROM, a RAM, and the like. Therefore, the above “unit” is mainly realized by a computer program executed by the CPU. .

The air-conditioning operation acquisition unit 101 is connected to the touch panel 2 and acquires an air-conditioning operation (in this embodiment, either a cooling operation or a heating operation) set by an occupant of a vehicle (not shown) operating the touch panel 2. To the operation state control unit 106 described later.
The target temperature acquisition unit 102 is also connected to the touch panel 2, acquires the target temperature of air conditioning set by operating the touch panel 2 by a vehicle occupant, and outputs the target temperature to the operation state control unit 106 described later.
The indoor temperature acquisition unit 103 is connected to an indoor temperature sensor 3 mounted in a vehicle interior of a vehicle (not shown), acquires the temperature of the vehicle interior (hereinafter referred to as the indoor temperature) detected by the indoor temperature sensor 3 and operates. Output to the state control unit 106.
The outdoor temperature acquisition unit 104 is connected to an outdoor temperature sensor 4 mounted on a vehicle (not shown), acquires an outdoor temperature detected by the outdoor temperature sensor 4 (hereinafter referred to as outdoor temperature), and an operation state control unit It outputs to 106.
The solar radiation amount acquisition unit 105 is connected to a solar radiation amount sensor 5 mounted on a vehicle (not shown), acquires the solar radiation amount detected by the solar radiation amount sensor 5, and outputs it to the operation state control unit 106.

  When the operation state control unit 106 acquires the air conditioning operation set by the vehicle occupant from the air conditioning operation acquisition unit 101, the cooling two-way valve 13, the three-way valve 17, and the air mixing plate 22 are matched to the set air conditioning operation. Change the setting. Further, based on the target temperature acquired from the target temperature acquisition unit 102, the indoor temperature acquired from the indoor temperature acquisition unit 103, the outdoor temperature acquired from the outdoor temperature acquisition unit 104, and the solar radiation amount acquired from the solar radiation amount acquisition unit 105, The rotational speed of the electric compressor 11 and the blower 21 is controlled. Further, as will be described in detail later, when the air conditioning operation is a cooling operation, the evaporator temperature detected by the temperature sensor 18s is also used for control, and when the air conditioning operation is a heating operation, it is detected by the pressure sensor 11s. The refrigerant pressure is also used for control.

The battery temperature acquisition unit 107 is connected to the battery temperature sensor 50 s, acquires the battery temperature of the secondary battery 50, and outputs it to the cooling necessity determination unit 108.
The cooling necessity determination unit 108 determines whether or not the secondary battery 50 needs to be cooled based on the battery temperature acquired from the battery temperature acquisition unit 107, and outputs the determination result to the battery cooling unit 109.
The battery cooling unit 109 is connected to the battery cooling two-way valve 42 and the cooling water pump 43 described above with reference to FIG. 1. When battery cooling is necessary, the battery cooling unit 109 opens the battery cooling two-way valve 42. The refrigerant gas is allowed to flow through the battery cooling refrigerant pipe 44, and the cooling water pump 43 is driven to circulate the cooling water.
Further, the battery cooling unit 109 outputs a message to that effect to the operation state control unit 106 and the cooling condition collection unit 111 when starting the battery cooling.

When the operation state control unit 106 receives the information indicating that the battery cooling is started from the battery cooling unit 109, the operation state control unit 106 increases the cooling capacity by the amount of the battery cooling during the cooling operation. However, there may be a case where there is no room for increasing the cooling capacity. In such a case, battery cooling is performed by using a part of the cooling capacity for air conditioning. Further, during the heating operation, the refrigerant gas is supplied to the battery cooling refrigerant pipe 44 and the battery cooling heat exchanger 41 by temporarily switching to the cooling operation.
Further, when the battery cooling occurs, the operation state control unit 106 outputs the operation conditions at that time (the contents of the air conditioning operation, the target temperature, the indoor temperature, the outdoor temperature, the amount of solar radiation, etc.) to the cooling condition collection unit.

In addition to the operating conditions when battery cooling occurs, the cooling condition collection unit 111 also provides information on the traveling state such as the traveling speed of the vehicle, position information, and the traveling distance and traveling time from the start of traveling. Collect as an occurrence condition. That is, the traveling condition acquisition unit 110 is connected to the cooling condition collection unit 111, and the vehicle speed sensor 6 and the navigation device 7 are connected to the traveling condition acquisition unit 110. For this reason, the cooling condition collection unit 111 can acquire the travel speed detected by the vehicle speed sensor 6 via the travel state acquisition unit 110. In addition, with regard to information such as position information, travel distance from the start of travel, and travel time, information that the navigation device 7 has can be acquired via the travel state acquisition unit 110.
Further, the cooling condition collection unit 111 is connected to the wireless communication device 8 and transmits the collected battery cooling generation conditions to an external server, and determines whether the battery cooling generation conditions need to be stored. . If it is determined that storage is necessary, part of the battery cooling generation condition is output to the cooling generation storage unit 112. The method for determining whether or not the storage of the battery cooling generation condition is necessary, and the battery cooling generation condition output to the cooling generation storage unit 112 when it is determined that storage is necessary will be described in detail later.
The cooling generation storage unit 112 stores the information received from the cooling condition collection unit 111 in a readable state.

B. Air conditioning control processing:
FIG. 3 shows a flowchart of the air conditioning control process executed by the air conditioning control device 100 of the present embodiment. As shown in the drawing, when the air conditioning control process is started, first, the air conditioning operation set by the vehicle occupant is acquired (S100). As described above with reference to FIG. 2, the vehicle occupant can set the air conditioning operation of the cooling operation or the heating operation to the air conditioning control device 100 by operating the touch panel 2.
Subsequently, the target temperature of the air conditioning set by the vehicle occupant is acquired (S101). As described above with reference to FIG. 2, the vehicle occupant can also set the target temperature for air conditioning by operating the touch panel 2.
Furthermore, the indoor temperature, the outdoor temperature, and the solar radiation amount detected by the indoor temperature sensor 3, the outdoor temperature sensor 4, and the solar radiation amount sensor 5 are acquired (S102).

And based on information, such as these target temperature, indoor temperature, outdoor temperature, and the amount of solar radiation, the target temperature (henceforth, target blowing temperature Tao) of the air which blows off into a vehicle interior is calculated (S103). For example, if the room temperature is higher than the target temperature during the cooling operation, the room temperature needs to be lowered, so that the target blowing temperature Tao is lowered. Naturally, the target blowing temperature Tao becomes lower as the indoor temperature becomes higher than the target temperature.
Further, the higher the outdoor temperature or the greater the amount of solar radiation, the easier the indoor temperature rises. Therefore, the target blowing temperature Tao needs to be lowered. Thus, the target blowing temperature Tao is determined based on information such as the target temperature, the indoor temperature, the outdoor temperature, and the amount of solar radiation. In the present embodiment, the target blowing temperature Tao is calculated using the following calculation formula.
Target outlet temperature Tao = K1, target temperature-K2, room temperature
-K3, outdoor temperature-K4, solar radiation + C
Here, K1 to K4 are proportional coefficients, and C is a correction constant.

  Subsequently, it is determined whether or not the air-conditioning operation set by the vehicle occupant is a cooling operation (S104), and if it is a cooling operation (S104: yes), the cooling two-way valve 13, the three-way valve 17. Switch the air mixing plate 22 to the cooling operation state (S105). In the cooling operation state, the cooling two-way valve 13 is opened, and the three-way valve 17 is switched to a state in which the refrigerant gas flows toward the evaporator 18. Further, the air mixing plate 22 is switched to a state that prevents air from flowing into the indoor condenser 12.

  FIG. 5 shows the operation of the air conditioner 10 in the cooling operation state. As described above with reference to FIG. 1, various refrigerant pipes are provided in the air conditioner 10, but in the cooling operation state, the refrigerant gas flows through the refrigerant pipes indicated by thick solid lines in FIG. 5. . In addition, the arrow attached | subjected along refrigerant | coolant piping in FIG. 5 represents the direction through which refrigerant gas flows. Hereinafter, the operation of the air conditioner 10 in the cooling operation state will be described with reference to FIG.

In the cooling operation state, by operating the electric compressor 11, the refrigerant gas compressed to a high pressure is pumped to the refrigerant pipe. The high-pressure refrigerant gas fed under pressure is supplied to the outdoor condenser 15 via the indoor condenser 12 and the cooling two-way valve 13.
The refrigerant piping from the indoor condenser 12 to the outdoor condenser 15 is divided into a path passing through the cooling two-way valve 13 and a path passing through the first expansion valve 14. However, since the cooling two-way valve 13 is opened in the cooling operation state, the refrigerant gas avoids the first expansion valve 14 having a large passage resistance, and exclusively passes through the cooling two-way valve 13. It is supplied to the outdoor condenser 15. In FIG. 5, the refrigerant pipe passing through the first expansion valve 14 is indicated by a thin broken line, indicating that the refrigerant gas does not flow through this part of the refrigerant pipe.

Further, when the refrigerant gas is compressed to a high pressure by the electric compressor 11, work is received from the outside (in this case, the electric compressor 11), so that the internal energy increases. As a result, the refrigerant gas is pumped from the electric compressor 11. The refrigerant gas is high pressure and high temperature. Then, the high-temperature and high-pressure refrigerant gas flows from the indoor condenser 12 into the outdoor condenser 15 via the cooling two-way valve 13.
The outdoor condenser 15 is a heat exchanger, and is adapted to receive air from a vehicle running wind or a blower (not shown). For this reason, the temperature of the high-temperature refrigerant gas flowing into the outdoor condenser 15 is lowered by exchanging heat with the surrounding air.
The indoor condenser 12 into which the high-temperature and high-pressure refrigerant gas compressed by the electric compressor 11 first flows is also a heat exchanger. As shown in FIG. 5, the indoor condenser 12 is an air mixing plate. 22 is in a state where no wind hits. For this reason, in the cooling operation state, the indoor condenser 12 does not actually radiate the refrigerant gas, and is radiated exclusively by the outdoor condenser 15.

The high-pressure refrigerant gas radiated and cooled by the outdoor condenser 15 is decompressed and expanded when passing through the second expansion valve 16. At this time, since the expanding refrigerant gas works to the outside, the internal energy is reduced. Therefore, the temperature of the refrigerant gas cooled by the heat radiation by the outdoor condenser 15 is further reduced.
In the cooling operation state, the three-way valve 17 is switched to a state in which the refrigerant gas is supplied to the evaporator 18, so that the refrigerant gas that has been decompressed and expanded by the second expansion valve 16 is supplied to the evaporator 18. Is done. For this reason, when the blower 21 is rotated and air is blown toward the evaporator 18, the air cooled by the low-temperature refrigerant gas becomes cold air and flows out of the evaporator 18, and is then guided by the air mixing plate 22. The air is blown into the room from the air passage 20.

The low-temperature refrigerant gas supplied to the evaporator 18 rises in temperature by absorbing the heat of air by the evaporator 18 and flows into the accumulator 19 in this state.
In the accumulator 19, the refrigerant gas is separated into a liquid phase portion and a gas phase portion, and the refrigerant gas in the gas phase portion is supplied to the electric compressor 11 and compressed by the electric compressor 11. That is, since the electric compressor 11 compresses the refrigerant gas that has absorbed heat from the air by the evaporator 18, the temperature of the compressed refrigerant gas greatly increases. Then, after the high-temperature and high-pressure refrigerant gas is guided to the outdoor condenser 15 to dissipate heat, the second expansion valve 16 decompresses and expands to generate low-temperature refrigerant gas, and the low-temperature refrigerant gas is led to the evaporator 18. Absorbs heat from the air. Therefore, when this series of operations is viewed as a whole, the operation is like a pump in which the heat of the air blown by the blower 21 is pumped by the evaporator 18 and discharged to the outside by the outdoor condenser 15. For this reason, the thermal cycle described above is sometimes called a “heat pump”.

  The operation of the air conditioner 10 in the cooling operation state has been described above. In the air conditioning control process shown in FIG. 3, when it is determined that the air conditioning operation is set to the cooling operation (S104: yes), the cooling two-way valve 13 or the three-way valve 17 is used to perform the above-described operation. The setting of the air mixing plate 22 is switched (S105). That is, the cooling two-way valve 13 is in an open state, the three-way valve 17 is in a state in which refrigerant gas is supplied to the evaporator 18, and the air mixing plate 22 allows air to flow into the indoor condenser 12. Switch to the blocking state.

  Subsequently, based on the target outlet temperature Tao calculated in S103, a target temperature of the evaporator 18 (hereinafter, target evaporator temperature Teo) is determined (S106). Various known methods can be used for determining the target evaporator temperature Teo. In this embodiment, the target evaporator temperature Teo is determined by referring to a map in which an appropriate target evaporator temperature Teo is set with respect to the target outlet temperature Tao.

Thereafter, based on the temperature difference between the target evaporator temperature Teo and the actual temperature of the evaporator 18 (hereinafter referred to as the evaporator temperature Te), the amount of change in the rotational speed Rc of the electric compressor 11 (hereinafter referred to as the rotational speed change amount). ΔRc) is determined (S107). The evaporator temperature Te can be detected using a temperature sensor 18 s mounted on the evaporator 18.
Various known methods can be used for determining the rotational speed change amount ΔRc of the electric compressor 11 based on the temperature difference between the target evaporator temperature Teo and the evaporator temperature Te. The reason why the rotational speed change amount ΔRc can be determined from the temperature difference between the temperature Teo and the evaporator temperature Te can be understood by considering the following.
For example, it is assumed that the target evaporator temperature Teo and the evaporator temperature Te are the same. In this case, since it is not necessary to change the current rotation speed Rc, the rotation speed change amount ΔRc is “0”. On the other hand, when the target evaporator temperature Teo is lower than the evaporator temperature Te, it is necessary to increase the cooling capacity. Therefore, the rotational speed change amount ΔRc is a positive value. Further, as the target evaporator temperature Teo becomes lower than the evaporator temperature Te, the absolute value of the rotational speed change amount ΔRc increases. On the other hand, when the target evaporator temperature Teo is higher than the evaporator temperature Te, it is considered that the cooling capacity is too large, and thus the rotation speed change amount ΔRc is a negative value. Further, as the target evaporator temperature Teo becomes higher than the evaporator temperature Te, the negative absolute value of the rotational speed change amount ΔRc increases.
As is clear from the above description, if the temperature difference between the target evaporator temperature Teo and the evaporator temperature Te is known, the rotational speed change amount ΔRc of the electric compressor 11 can be determined accordingly.

When the rotational speed change amount ΔRc is thus obtained (S107), a temporary target rotational speed of the electric compressor 11 (hereinafter referred to as temporary target rotational speed Rtmp) is calculated using the following equation (S111).
Temporary target rotational speed Rtmp = rotational speed Rc + rotational speed change amount ΔRc
The reason why the calculated rotational speed is the “temporary” target rotational speed will be described later.

The process when the air-conditioning operation set by the vehicle occupant is the cooling operation, that is, when “yes” is determined in S104 has been described. On the other hand, when the air conditioning operation is set to the heating operation (S104: no), the following processing is performed.
First, the cooling two-way valve 13, the three-way valve 17, and the air mixing plate 22 are switched to the heating operation state (S108). In the heating operation state, the cooling two-way valve 13 is closed, and the three-way valve 17 is switched to a state where the refrigerant gas bypasses the evaporator 18. The air mixing plate 22 is switched to a state in which air flows into the indoor condenser 12. Thus, the heating operation can be realized by the air conditioner 10 by switching the setting of the cooling two-way valve 13, the three-way valve 17, and the air mixing plate 22. This point will be described below.

FIG. 6 shows the operation of the air conditioner 10 in the heating operation state. As in the case of FIG. 5 showing the cooling operation state described above, also in FIG. 6, the refrigerant pipe through which the refrigerant gas flows is represented by a thick solid line, and the direction in which the refrigerant gas flows is represented by an arrow attached along the refrigerant pipe. .
Even in the heating operation state, similarly to the above-described cooling operation state, by operating the electric compressor 11, the refrigerant gas compressed to a high pressure is pumped to the refrigerant pipe. Since the refrigerant gas is worked from the electric compressor 11 when compressed to a high pressure, the internal energy increases, the temperature rises, and the refrigerant gas is supplied to the indoor condenser 12 as a high-temperature and high-pressure refrigerant gas. Is done.
Further, the indoor condenser 12 is a heat exchanger, and in the heating operation state, the air blown by the blower 21 is guided to the indoor condenser 12 as shown in FIG. A mixing plate 22 is set. For this reason, when a high-temperature refrigerant gas is supplied to the indoor condenser 12, the air blown by the blower 21 is heated and blown into the room from the blowing passage 20 as warm air.
Further, as the air is heated, the high-temperature and high-pressure refrigerant gas supplied to the indoor condenser 12 flows out of the indoor condenser 12 in a cooled state.

  In the heating operation, the cooling two-way valve 13 is closed. For this reason, the high-pressure refrigerant gas that has flowed out of the indoor condenser 12 passes through the path in which the first expansion valve 14 is provided, as shown in FIG. At this time, the high-pressure refrigerant gas is decompressed and expanded by the first expansion valve 14 to reduce the internal energy. Therefore, the temperature of the refrigerant gas that has been radiated and cooled by the indoor condenser 12 is further reduced. Then, the refrigerant gas flows into the outdoor condenser 15. As described above, since the outdoor condenser 15 is blown by the driving wind of the vehicle or the blower (not shown), when the low-temperature refrigerant gas flows into the outdoor condenser 15, the refrigerant gas is heated by the ambient air. Absorbs the temperature rises.

Thereafter, the refrigerant gas whose temperature has increased in the outdoor condenser 15 passes through the second expansion valve 16 and reaches the three-way valve 17. As described above, since the three-way valve 17 is set in a state in which the refrigerant gas bypasses the evaporator 18 in the heating operation, the refrigerant gas that has reached the three-way valve 17 does not pass through the evaporator 18 and is accumulated. Flows into the radiator 19.
In the cooling operation described above, the refrigerant gas is decompressed and expanded by the second expansion valve 16 and the temperature is lowered. In the heating operation, the refrigerant gas is decompressed and expanded by the second expansion valve 16 and the temperature is not lowered. . This is because in the heating operation, the first expansion valve 14 is already decompressed and expanded, and the pressure of the refrigerant gas is reduced.

  In the accumulator 19, the refrigerant gas is separated into a liquid phase portion and a gas phase portion, and the refrigerant gas in the gas phase portion is supplied to the electric compressor 11 and compressed by the electric compressor 11. That is, in the heating operation, the refrigerant gas that has absorbed heat from the air by the outdoor condenser 15 is compressed by the electric compressor 11, so the temperature of the compressed refrigerant gas greatly increases. Then, after the refrigerant gas that has risen to a high temperature is guided to the indoor condenser 12 to radiate heat, the refrigerant is further decompressed and expanded by the first expansion valve 14 to generate a lower temperature refrigerant gas. To the outdoor condenser 15 to absorb the heat of the air. Accordingly, if this series of operations is viewed as a whole, the operation is like a pump in which the heat extracted from the air outside the vehicle compartment by the outdoor condenser 15 is exhausted to the air in the air passage 20 by the indoor condenser 12. become. From this, it can be considered that the thermal cycle described above is different from the previously described cooling operation in the direction of operation of the thermal cycle, that is, the direction in which heat is pumped out and discharged.

  In the air conditioning control process shown in FIG. 3, when it is determined that the air conditioning operation is set to the heating operation (S104: no), the cooling two-way valve 13 or the three-way valve 17 is used to perform the above-described operation. The setting of the air mixing plate 22 is switched (S108). That is, the cooling two-way valve 13 is closed, the three-way valve 17 is in a state in which the refrigerant gas bypasses the evaporator 18, and the air mixing plate 22 is switched to a state in which air flows into the indoor condenser 12. .

  Subsequently, in the heating operation, a target pressure (hereinafter referred to as a target refrigerant pressure Peo) at which the electric compressor 11 pumps the refrigerant gas is determined based on the target outlet temperature Tao calculated in S103 (S109). Various known methods can be used for determining the target refrigerant pressure Peo. In this embodiment, it is determined by referring to a map in which an appropriate target refrigerant pressure Peo is set with respect to the target blowing temperature Tao.

Thereafter, based on the pressure difference between the target refrigerant pressure Peo and the actual pressure at which the electric compressor 11 pumps the refrigerant gas (hereinafter, the actual refrigerant pressure Pre), the amount of change in the rotational speed Rc of the electric compressor 11 ( Hereinafter, the rotational speed change amount ΔRc) is determined (S110). The actual refrigerant pressure Pre can be detected using a pressure sensor 11 s attached to the refrigerant pipe on the downstream side of the electric compressor 11.
Various known methods can be used for determining the rotational speed change amount ΔRc of the electric compressor 11 based on the pressure difference between the target refrigerant pressure Peo and the actual refrigerant pressure Pre. The reason why the rotational speed change amount ΔRc can be determined from the pressure difference between Peo and the actual refrigerant pressure Pre can be understood by considering the following.
For example, if the target refrigerant pressure Peo and the actual refrigerant pressure Pre are the same, there is no need to change the current rotation speed Rc, so the rotation speed change amount ΔRc is “0”. On the other hand, when the target refrigerant pressure Peo is lower than the actual refrigerant pressure Pre, it is necessary to increase the heating capacity, so the rotational speed change amount ΔRc is a positive value. Further, as the target refrigerant pressure Peo becomes lower than the actual refrigerant pressure Pre, the absolute value of the rotational speed change amount ΔRc increases. On the contrary, when the target refrigerant pressure Peo is higher than the actual refrigerant pressure Pre, it is considered that the heating capacity is too large, so the rotation speed change amount ΔRc becomes a negative value. Further, as the target refrigerant pressure Peo becomes higher than the actual refrigerant pressure Pre, the negative absolute value of the rotation speed change amount ΔRc increases.
As is clear from the above description, if the pressure difference between the target refrigerant pressure Peo and the actual refrigerant pressure Pre is known, the rotational speed change amount ΔRc of the electric compressor 11 can be determined accordingly.

When the rotation speed change amount ΔRc is obtained in the heating operation in this way (S110), the temporary target rotation speed of the electric compressor 11 (hereinafter referred to as the temporary target rotation speed Rtmp) is calculated using the following equation, similarly to the cooling operation. ) Is calculated (S111).
Temporary target rotational speed Rtmp = rotational speed Rc + rotational speed change amount ΔRc

  As described above, even when the air conditioning operation set by the vehicle occupant is either the cooling operation or the heating operation, the temporary target rotational speed of the electric compressor 11 (that is, the temporary target rotational speed Rtmp) is calculated. (S111).

Subsequently, it is determined whether or not the temporary target rotational speed Rtmp exceeds the maximum rotational speed Rmax of the electric compressor 11 (S112 in FIG. 4). If the temporary target rotational speed Rtmp does not exceed the maximum rotational speed Rmax (S112: no), the temporary target rotational speed Rtmp is set to the “real” target rotational speed Rm (S114).
On the other hand, when the temporary target rotational speed Rtmp exceeds the maximum rotational speed Rmax (S112: yes), the maximum rotational speed Rmax is set to the target rotational speed Rm of the electric compressor 11 (S113).

  When the target rotational speed Rm of the electric compressor 11 is thus determined (S113 or S114), the electric compressor 11 is driven at the determined target rotational speed Rm (S115). That is, the current value or AC frequency applied to the electric compressor 11 is controlled so that the rotational speed Rc of the electric compressor 11 approaches the target rotational speed Rm.

Subsequently, the battery temperature of the secondary battery 50 is acquired (S116). As described above with reference to FIG. 2, the battery temperature can be detected using the battery temperature sensor 50s.
And based on the acquired battery temperature, it is judged whether the battery cooling of the secondary battery 50 is required (S117). Whether or not battery cooling is necessary can be determined in consideration of various conditions. Simply, it may be determined that battery cooling is required when the battery temperature exceeds a predetermined threshold temperature.
As a result, when it is determined that battery cooling is necessary (S117: yes), a battery cooling process described later is started (S200).

On the other hand, when it is determined that battery cooling is unnecessary (S117: no), it is determined whether or not the air conditioning control process shown in FIGS. 3 and 4 is to be ended (S118), and the process is not ended. (S118: no), after returning to the head and acquiring the air conditioning operation set by the vehicle occupant (S100 in FIG. 3), the above-described series of processing is executed.
On the other hand, when it is determined that the process is to be ended (S118: no in FIG. 4), the air-conditioning control process shown in FIGS. 3 and 4 is ended.

C. Battery cooling treatment:
7 and 8 show a flowchart of the battery cooling process. This process is a process started by the air conditioning control device 100 when it is determined that the battery cooling is necessary in the air conditioning control process described above (S117: yes in FIG. 4).
As shown in FIG. 7, when the battery cooling process (S200) is started, first, the current operating condition of the air conditioner 10, that is, whether the air conditioning operation is the cooling operation or the heating operation, and the electric compressor 11 is stored (S201). The reason for this is that, as described above with reference to FIG. 1, the battery cooling device 40 performs battery cooling using the heat pump of the air conditioner 10. Therefore, when the battery cooling is started, the air conditioner 10 based on the setting of the vehicle occupant. This is because the operating conditions of the change. Therefore, after the battery cooling is completed, the operating conditions of the air conditioner 10 are stored so that the original operating conditions can be restored.

Subsequently, it is determined whether or not the current air conditioning operation of the air conditioner 10 is a cooling operation (S202). As a result, when the current air conditioning operation is the heating operation (S202: no), the setting of the cooling two-way valve 13 and the three-way valve 17 is switched to the setting of the cooling operation state (S203). Note that the air mixing plate 22 is set in the heating operation state described above with reference to FIG. 6, that is, in a state where the air from the blower 21 is guided to the indoor condenser 12.
Here, an outline of a method for cooling the battery during the heating operation will be described.

FIG. 9 shows operations of the air conditioner 10 and the battery cooling device 40 when the battery is cooled during the heating operation. As in the case of FIG. 5 or FIG. 6 described above, also in FIG. 9, the refrigerant pipe through which the refrigerant gas flows and the battery cooling refrigerant pipe 44 are represented by thick solid lines, and the direction in which the refrigerant gas flows is attached along the refrigerant pipe. It is represented by an arrow.
As shown in FIG. 9, when battery cooling is performed, the cooling two-way valve 13 and the three-way valve 17 are set in the same manner as in the cooling operation shown in FIG. The three-way valve 17 is set so that the refrigerant gas is supplied to the evaporator 18.
For this reason, when the electric compressor 11 is operated, the refrigerant gas that has been compressed to a high temperature and a high pressure is supplied to the indoor condenser 12 as in the cooling operation described above with reference to FIG. After the heat is radiated by the indoor condenser 12, the high-pressure refrigerant gas that flows into the outdoor condenser 15 through the cooling two-way valve 13 and is further radiated by the outdoor condenser 15 is cooled. The temperature of the refrigerant gas further decreases by expanding under reduced pressure. The low-temperature refrigerant gas thus generated is supplied to the evaporator 18 by the three-way valve 17 and absorbs the heat of the air by the evaporator 18 and then flows into the accumulator 19.

Here, from the refrigerant pipe connecting the three-way valve 17 and the evaporator 18, a battery cooling refrigerant pipe 44 is branched on the way, and this battery cooling refrigerant pipe 44 is connected to the battery cooling two-way valve 42. Has been. Since the battery cooling two-way valve 42 is closed while the battery is not cooled, the refrigerant gas flowing from the three-way valve 17 toward the evaporator 18 does not flow into the battery cooling refrigerant pipe 44. Absent.
However, when battery cooling is performed, since the battery cooling two-way valve 42 is opened, a part of the refrigerant gas flowing toward the evaporator 18 is diverted to the battery cooling refrigerant pipe 44. The refrigerant gas flowing into the battery cooling refrigerant pipe 44 passes through the battery cooling heat exchanger 41 via the battery cooling two-way valve 42, and then between the evaporator 18 and the accumulator 19, The refrigerant gas flows from the evaporator 18 toward the accumulator 19 (see FIG. 9).

As described above, since the refrigerant gas flowing from the three-way valve 17 toward the evaporator 18 is a low-temperature refrigerant gas expanded under reduced pressure by the second expansion valve 16, the low-temperature refrigerant gas is supplied to the battery cooling heat exchanger 41. Will be. Therefore, the cooling water pump 43 is driven to circulate the cooling water through the cooling water pipe 45. If it carries out like this, cold water will be produced | generated by cooling cooling water with low-temperature refrigerant gas, and it will become possible to cool the secondary battery 50 using the cold water.
In FIG. 9, the cooling water pipe 45 is indicated by a thick broken line to indicate that the cooling water is flowing. A broken-line arrow displayed along the cooling water pipe 45 represents the direction in which the cooling water flows.

In the battery cooling process shown in FIG. 7, when the current air conditioning operation is determined to be the heating operation (S202: no), the setting of the cooling two-way valve 13 and the three-way valve 17 is set to the cooling operation in order to perform the above-described battery cooling. Switching to the setting of the state (S203).
Subsequently, a predetermined rotation speed (hereinafter referred to as battery cooling rotation speed) set in advance as the rotation speed for battery cooling is set as the target rotation speed Rm of the electric compressor 11 (S204). In this embodiment, the battery cooling rotation speed is described as being set to an appropriate value in advance, but may be changed according to the battery temperature, the outdoor temperature, or the like.

Thereafter, the battery cooling memory flag is set to ON (S209). The battery cooling storage flag is a flag indicating whether or not to store the occurrence of battery cooling. The state where the battery cooling storage flag is set to ON indicates that the occurrence of battery cooling is stored. The state in which the cooling memory flag is set to OFF represents that the occurrence of battery cooling is not stored.
When the battery cooling memory flag is set in this manner, the battery cooling two-way valve 42 is opened and the cooling water pump 43 is driven (S210), and then the electric compressor 11 is driven at the target rotational speed Rm (S211). As a result, the battery cooling of the secondary battery 50 is started as described above with reference to FIG.

In the above, the process of starting the battery cooling when the air conditioning operation when the battery needs to be cooled is the heating operation (S202: no) has been described. On the other hand, when the air conditioning operation is the cooling operation (S202: yes), it is not necessary to switch the setting of the cooling two-way valve 13 or the three-way valve 17.
Here, an outline of a method for cooling the battery during the cooling operation will be briefly described.

FIG. 10 shows operations of the air conditioner 10 and the battery cooling device 40 when the battery is cooled during the cooling operation. Like FIG. 9 explaining the case where the battery cooling is performed during the heating operation, also in FIG. 10, the refrigerant pipe through which the refrigerant gas flows and the battery cooling refrigerant pipe 44 are represented by thick solid lines, and the direction in which the refrigerant gas flows is represented by the refrigerant pipe. It is represented by an arrow attached along the line.
As apparent from a comparison between FIG. 9 and FIG. 10, although there is a difference in the state in which the air mixing plate 22 is set, the battery cooling is also performed during the cooling operation (see FIG. 9). When the battery is cooled (see FIG. 10), the refrigerant gas and the cooling water flow are the same. Therefore, the setting of the cooling two-way valve 13 and the three-way valve 17 is the same as that shown in FIG. 9, and when the battery cooling is started during the cooling operation, the cooling two-way valve 13 and the three-way valve 17 are set. There is no need to change the setting. Incidentally, it is not necessary to change the setting of the air mixing plate 22.

Even when the battery is cooled during the cooling operation, the refrigerant gas compressed by the electric compressor 11 to high temperature and high pressure is supplied to the indoor condenser 12 and flows into the outdoor condenser 15 via the cooling two-way valve 13. To do. The high-pressure refrigerant gas radiated and cooled by the outdoor condenser 15 is decompressed and expanded by the second expansion valve 16, so that the temperature further decreases. The low-temperature refrigerant gas generated in this way is divided into two downstream of the three-way valve 17, and one refrigerant gas flows into the accumulator 19 via the evaporator 18. The other refrigerant gas passes through the battery cooling refrigerant pipe 44, passes through the battery cooling heat exchanger 41 from the battery cooling two-way valve 42, and then flows into the accumulator 19.
In the battery cooling heat exchanger 41, the low-temperature refrigerant gas thus supplied and the cooling water circulating through the cooling water pipe 45 by the cooling water pump 43 exchange heat to generate cold water, and the cold water generates secondary battery. 50 is cooled.

  As described above, when battery cooling occurs during the cooling operation (S202 of FIG. 7: yes), a part of the refrigerant gas that has been flowing from the three-way valve 17 to the evaporator 18 until then is used for battery cooling. The battery is cooled by diverting the refrigerant into the refrigerant pipe 44. For this reason, if the battery cooling is simply started, the supply of the refrigerant gas for the cooling operation that has been performed until then is insufficient. Therefore, in order to increase the flow rate of the refrigerant gas pumped by the electric compressor 11, the rotational speed Rc of the electric compressor 11 is increased.

Therefore, when battery cooling occurs during the cooling operation (S202: yes), first, the battery cooling rotation speed is added to the rotation speed Rc of the electric compressor 11 during the cooling operation (S205). . Then, it is determined whether or not the obtained addition value is larger than the maximum rotational speed Rmax of the electric compressor 11 (S206).
As a result, when the added value is larger than the maximum rotation speed Rmax (S206: yes), the maximum rotation speed Rmax is set as the target rotation speed Rm of the electric compressor 11 instead of the addition value (S207), and then the battery is cooled. The storage flag is set to ON (S209). As described above, the battery cooling storage flag is a flag indicating whether or not to store the occurrence of battery cooling, and the state where the battery cooling storage flag is turned on indicates that the occurrence of battery cooling is stored. ing.
Thereafter, the battery cooling two-way valve 42 is opened, and the cooling water pump 43 is driven (S210), and then the electric compressor 11 is driven at the target rotational speed Rm, whereby the secondary battery 50 is cooled. Start (S211).

On the other hand, when the addition value obtained by adding the battery cooling rotation speed to the rotation speed Rc of the electric compressor 11 during the cooling operation is smaller than the maximum rotation speed Rmax (S206: no), the addition value is set to the electric compressor 11. Is set as the target rotational speed Rm (S208).
In this case, the battery cooling two-way valve 42 is opened without setting the battery cooling memory flag ON, and the cooling water pump 43 is driven (S210), and then the electric compressor 11 is rotated to the target rotation. Battery cooling of the secondary battery 50 is started by driving at the speed Rm (S211). If the added value is smaller than the maximum rotation speed Rmax (S206: no), the reason why the battery cooling storage flag is not set to ON despite the battery cooling will be described in detail later.

When the electric compressor 11 is driven at the target rotational speed Rm as described above (S211), it is determined whether or not the battery temperature of the secondary battery 50 has decreased to a predetermined target temperature (S212). As a result, when the battery temperature has not decreased to the target temperature (S212: no), the battery cooling is continued, but when the battery temperature decreases to the target temperature (S212: yes), the battery cooling two-way valve 42 is continued. Is closed and the cooling water pump 43 is stopped (S213 in FIG. 8). By doing so, the battery cooling is stopped.
Thereafter, the condition when the battery cooling occurs (that is, the battery cooling generation condition) is transmitted to an external server (S214). As described above with reference to FIG. 2, the wireless communication device 8 is connected to the air conditioning control device 100 and is transmitted to an external server using the wireless communication device 8.

  FIG. 11 illustrates battery cooling generation conditions transmitted to an external server. In the illustrated example, the battery cooling generation conditions include the air conditioning operation of the air conditioner 10 when battery cooling occurs, the date and time when battery cooling starts and ends, the room temperature when the battery cooling occurs, the outdoor temperature, the vehicle traveling speed, Information such as the elapsed time from the start of travel (elapsed time from the start of the engine if the vehicle is equipped with an engine), the travel distance from the start of travel of the vehicle (the travel distance from the start of the engine if the vehicle is equipped with an engine), etc. Send it to the server.

Among these pieces of information, the room temperature at the time of battery cooling, the outdoor temperature, and the traveling speed of the vehicle are stored when the operating conditions of the air conditioner 10 are stored in S201 of FIG. Keep it.
As for the air conditioning operation of the air conditioner 10, there are three cases of “heating”, “low load cooling”, and “high load cooling” as shown in FIG. Is stored when the operating condition of the air conditioner 10 is stored in S201 of FIG. Further, “during low load cooling” or “during high load cooling” is stored based on the determination result in S206 of FIG. That is, when the value obtained by adding the battery cooling rotational speed to the current rotational speed Rc of the electric compressor 11 is less than the maximum rotational speed Rmax of the electric compressor 11 (S206: no), the air conditioning operation of the air conditioner 10 is performed. Is stored as “low-load cooling”, and conversely, if it is greater than the maximum rotation speed Rmax (S206: yes), it is stored as “high-load cooling”.
Further, in the present embodiment, information collected by the navigation device 7 is acquired for the elapsed time from the start of travel of the vehicle and the travel distance. Of course, instead of obtaining from the navigation device 7, the air conditioning control device 100 may obtain from the vehicle control device.

  In addition, as battery cooling generation conditions, you may acquire the positional information on the vehicle at the time of battery cooling generation from the navigation apparatus 7. FIG. Furthermore, if it is possible to obtain from the navigation device 7, the condition of the road (for example, whether it is paved, whether it is a slope, the slope of the road, etc.) is also obtained as the battery cooling generation condition. Also good.

  In the external server, by accumulating the transmitted information, it is possible to clarify the conditions under which the battery cooling occurs, and the development efficiency of the battery cooling device 40 and the air conditioning system 1 can be improved. Become.

As described above, when the battery cooling generation condition is transmitted to an external server (S214 in FIG. 8), it is determined whether or not the battery cooling storage flag is set to ON (S215). As described above, the battery cooling storage flag is a flag indicating whether or not to store battery cooling.
As a result, when the battery cooling storage flag is set to ON (S215: yes), predetermined information selected in advance from various information transmitted to an external server indicates the occurrence of battery cooling. Information is stored in a memory (not shown) of the air conditioning control device 100 (S216). In the example shown in FIG. 11, two conditions of the air conditioning operation of the air conditioner 10 and the start date and time of battery cooling are selected from the conditions at the time of battery cooling occurrence (that is, battery cooling occurrence conditions). It memorize | stores as information to show.

On the other hand, when the battery cooling storage flag is not set to ON (S215: no), information indicating the occurrence of battery cooling is not stored. Therefore, the information indicating the battery cooling occurrence condition is transmitted to an external server every time the battery cooling occurs, but the information indicating the occurrence of the battery cooling is ON even if the battery cooling occurs. If it is not set to, it will not be stored.
For example, in the example shown in FIG. 11, battery cooling generation conditions associated with the generation of battery cooling for nine times are shown. Among these, the first battery cooling displayed at the top is the air conditioner 10. Battery cooling occurs during the air conditioning operation. Then, as described above with reference to FIG. 7, when battery cooling occurs during the heating operation (S202: no), the battery cooling storage flag is set to ON (S209). Accordingly, for the first battery cooling, two types of information, that is, the air conditioning operation when the battery cooling occurs and the date and time when the battery cooling starts, are stored in the memory of the air conditioning control device 100 as information indicating the occurrence of the battery cooling. In FIG. 11, the air conditioning operation at the time of the first battery cooling and the date and time of starting the battery cooling are surrounded by a broken-line rectangle. It is stored as the information to be shown.
Similarly to the first battery cooling, information indicating the occurrence of battery cooling is also stored for the second battery cooling in FIG.

In addition, in the third battery cooling shown third from the top in FIG. 11, battery cooling occurs during low-load cooling (that is, when “no” is determined in S206 of FIG. 7). If it is determined as “no” in S206, the battery cooling memory flag remains set to OFF. Therefore, for the third battery cooling, information indicating the occurrence of battery cooling is not stored in the memory of the air conditioning control device 100.
Similarly to the third battery cooling, information indicating the occurrence of battery cooling is not stored for the fourth battery cooling in FIG.

Further, in the fifth battery cooling shown fifth from the top in FIG. 11, the battery cooling occurs during high-load cooling (that is, when “yes” is determined in S206 of FIG. 7). If it is determined as “yes” in S206, the battery cooling storage flag is set to ON (see S209). Therefore, for the fifth battery cooling, as indicated by the dashed rectangle in FIG. 11, the two information of the air conditioning operation at the time of battery cooling and the date and time of battery cooling start indicate the occurrence of battery cooling. It is stored as information to be shown.
Here, as information indicating the occurrence of battery cooling, it is assumed that the date and time at the start of battery cooling is stored in addition to the air-conditioning operation at the time of battery cooling. May be stored. Alternatively, the date and time at the end of battery cooling may be stored instead of the date and time at the start of battery cooling.

  In this way, information indicating the occurrence of battery cooling is stored in a part of the generated battery cooling (in the example shown in FIG. 11, five times out of nine battery coolings). Moreover, even when the occurrence of battery cooling is stored, the stored information is only a part of the battery cooling generation condition transmitted to the external server. For this reason, even when the battery cooling frequently occurs, the occurrence of the battery cooling can be stored without consuming a large memory capacity of the air conditioning control device 100.

When the occurrence of battery cooling is stored as described above (S216), the battery cooling storage flag is set to OFF (S217). Further, even when the occurrence of battery cooling is not stored, the battery cooling storage flag is set to OFF (S217).
Then, after the operating state of the air conditioner 10 is returned to the state before the occurrence of battery cooling (S218), the battery cooling process shown in FIGS. 7 and 8 is terminated, and the air conditioning control process of FIGS. Return to.

  As described above in detail, if it is determined that the battery cooling of the secondary battery 50 is necessary during the execution of the air conditioning control process (S117: yes in FIG. 4), the battery cooling process (S200) is started. Then, as described above with reference to FIGS. 7 and 8, the battery cooling process is continued until the battery temperature of the secondary battery 50 decreases to a predetermined target temperature (see S212 in FIG. 7). Therefore, while the battery is being cooled, the air conditioning operation that has been performed by the air conditioner 10 until then is interrupted.

For example, when battery cooling occurs during the heating operation of the air conditioner 10, the operation state of the air conditioner 10 is switched from the operation state illustrated in FIG. 6 to the operation state illustrated in FIG. The operation state shown in FIG. 9 is the operation state of the cooling operation in which the heat of the air is absorbed by the evaporator 18 and the heat is radiated by the outdoor condenser 15 as a whole. For this reason, heating operation cannot be performed while the battery is being cooled.
Further, when battery cooling occurs during the heating operation of the air conditioner 10, the operation state of the air conditioner 10 is switched from the operation state illustrated in FIG. 5 to the operation state illustrated in FIG. In this case, there is no significant difference in the overall operation of the air conditioner 10, but in FIG. 5, all the refrigerant gas that has passed through the three-way valve 17 is supplied to the evaporator 18, whereas in FIG. Part of the refrigerant gas is diverted to the battery cooling refrigerant pipe 44. For this reason, in order to avoid a situation where the refrigerant gas supplied to the evaporator 18 is insufficient, it is necessary to increase the flow rate of the refrigerant gas to be pumped by increasing the rotational speed Rc of the electric compressor 11. However, since the rotational speed Rc of the electric compressor 11 cannot be made higher than the maximum rotational speed Rmax, the refrigerant gas supplied to the evaporator 18 becomes insufficient and the cooling capacity is reduced.

  And when these situations (that is, a situation where heating cannot be performed during the heating operation or a situation where the cooling capacity is reduced during the cooling operation) occur, the vehicle occupant thinks that the air conditioner 10 has malfunctioned. Therefore, it may occur that the air conditioner 10 is brought into inspection and repair. Of course, since there is no problem with the air conditioner 10, no matter how much it is inspected, the cause of the malfunction cannot be found, and the vehicle is returned to the owner. This not only requires a lot of time and effort for unnecessary inspection, but also causes the possibility that the owner of the vehicle may be distrusted with respect to the ability of inspection and repair.

In contrast, in the air conditioning control device 100 of the present embodiment described above, battery cooling occurs when battery cooling occurs during heating operation (S202: no in FIG. 7) or during cooling operation with a high load. In the case (S206: yes), as a result of setting the battery cooling storage flag to ON (S209), the occurrence of battery cooling is stored in the memory (S216 of FIG. 8). For this reason, when the air conditioner 10 is brought into the inspection / repair, the battery cooling history stored in the memory of the air conditioning control device 100 is read to check whether the cause of the air conditioner 10 brought into the inspection / repair is the battery cooling. It can be determined whether or not.
In addition, the information stored as the battery cooling history includes an air conditioning operation when battery cooling occurs and a date or date when battery cooling starts. Therefore, by checking these pieces of information, it can be easily determined whether or not the cause of the air conditioning malfunction is due to the occurrence of battery cooling. As a result, it is possible to avoid a situation in which a great deal of time is spent on useless inspections and the vehicle owner is distrusted with respect to inspection and repair capabilities.

In the above description, when the battery cooling occurs during the cooling operation at a low load (S206: no in FIG. 7), the battery cooling storage flag is kept OFF, and therefore the battery cooling occurs. Explained that it was never stored in memory. The reason for this is as follows.
First, when battery cooling occurs during a low-load cooling operation, the rotational speed Rc of the electric compressor 11 is increased even if a part of the refrigerant gas is diverted to the battery cooling refrigerant pipe 44. As a result, it is possible to compensate for the decrease in the refrigerant gas supplied to the evaporator 18. If the decrease in the refrigerant gas supplied to the evaporator 18 can be compensated for, the cooling capacity does not change before and after the battery cooling occurs. This is because repairs are not expected to be brought in.
However, even if the rotational speed Rc of the electric compressor 11 is increased, the refrigerant gas that is diverted to the battery cooling refrigerant pipe 44 is not necessarily compensated accurately. Therefore, the cooling capacity may change due to the change in the flow rate of the refrigerant gas supplied to the evaporator 18 before and after the battery cooling occurs. For this reason, even when battery cooling occurs during low-load cooling operation, the occurrence of battery cooling may be stored in the memory.
In this way, even if the vehicle occupant notices a slight change in cooling capacity and is brought into the inspection and repair of the air conditioner 10, it is possible to avoid a situation in which a wasteful inspection takes a lot of trouble. Become.

D. Modified example:
In the above-described embodiment, the case where battery cooling occurs during heating operation or when battery cooling occurs during low-load cooling operation has been described as storing the occurrence of battery cooling. In this way, even when the occurrence of battery cooling is mistaken for the malfunction of the air conditioner 10 and is brought into inspection and repair, it can be easily handled.
However, even when battery cooling occurs during heating operation or cooling operation at low load, if the vehicle occupant notices the occurrence of battery cooling, it can be mistaken for malfunction of the air conditioner 10 and brought into inspection and repair. It is thought that the nature is low. Therefore, in such a case, it is not necessary to store the occurrence of battery cooling.
Therefore, as will be described below, the air conditioning control device 150 according to the modified example notifies the vehicle occupant that battery cooling has occurred, and the vehicle occupant does not perform a confirmation operation for the notification. Stores the occurrence of battery cooling.

  FIG. 12 shows an internal structure of an air conditioning control device 150 according to a modification. The air conditioning control device 150 of the modification shown in FIG. 12 is provided with a confirmation request output unit 113 and a confirmation operation detection unit 114, compared to the air conditioning control device 100 of the present embodiment described above with reference to FIG. There is a big difference. Below, the air conditioning control apparatus 150 of a modification is demonstrated centering on difference with the air conditioning control apparatus 100 of a present Example mentioned above.

  As shown in FIG. 12, the air conditioning control device 150 of the modification also includes an air conditioning operation acquisition unit 101, a target temperature acquisition unit 102, an indoor temperature acquisition unit 103, an outdoor temperature acquisition unit 104, and a solar radiation amount acquisition unit 105. An operation state control unit 106, a battery temperature acquisition unit 107, a cooling necessity determination unit 108, a battery cooling unit 109, a travel state acquisition unit 110, a cooling condition collection unit 111, and a cooling generation storage unit 112. It has. Among these, except for the battery cooling unit 109 and the cooling condition collection unit 111, the operation of the other “units” is the same as that of the air conditioning control device 100 of the above-described embodiment, and thus description thereof is omitted here.

Even in the case of the modification, as in the case of the above-described embodiment, the battery cooling unit 109 opens the battery cooling two-way valve 42 and drives the cooling water pump 43 to cool the battery. Further, when starting the battery cooling, the fact is also output to the operation state control unit 106 and the cooling condition collection unit 111.
In addition to this, when the battery cooling unit 109 according to the modified example starts the battery cooling, the battery cooling unit 109 also outputs a message to that effect to the confirmation request output unit 113.
When the confirmation request output unit 113 is connected to the touch panel 2 and receives information from the battery cooling unit 109 to start battery cooling, the confirmation request output unit 113 notifies the vehicle occupant of the start of battery cooling and confirms the notification. Is output to the touch panel 2.

  FIG. 13 illustrates a screen for informing the start of battery cooling displayed on the touch panel 2. On the screen shown in the figure, it is informed that the battery cooling is started, and that the air-conditioning capacity is temporarily reduced during the battery cooling and that the user is prompted to press the confirmation button. By displaying such a screen, the vehicle occupant recognizes that the battery cooling is started, and recognizes that the air conditioning capability may be temporarily reduced during the battery cooling. Then, after confirming the display, a confirmation operation of pressing a confirmation button is performed.

As shown in FIG. 12, the touch panel 2 is also connected to the confirmation operation detection unit 114, and when the confirmation button is pressed on the touch panel 2, the confirmation operation detection unit 114 detects this and the cooling condition collection unit To 111.
Similarly to the cooling condition collection unit 111 of the present embodiment described above, the cooling condition collection unit 111 of the modification also collects various conditions when battery cooling occurs (see FIG. 11), and the wireless communication device 8 To send to an external server. In addition, it is determined whether or not to store the occurrence of battery cooling, and if it is determined to store, the information selected from the collected information is output to the cooling generation storage unit 112.

Here, the cooling condition collection unit 111 of the modified example confirms whether or not the confirmation button has been pressed on the touch panel 2 when determining whether or not to store the occurrence of battery cooling. When the confirmation button is pressed between the time when a predetermined confirmation time elapses after the image informing the start of battery cooling illustrated in FIG. 13 is displayed on the screen of the touch panel 2, the battery It is determined that there is no need to memorize the occurrence of cooling.
In this way, the vehicle occupant recognizes that battery cooling occurs, and that the air conditioning capability may temporarily decrease as battery cooling occurs. It is possible to avoid a situation in which the occurrence of battery cooling is memorized until there is a low possibility of being brought into inspection and repair.
Below, the air conditioning control apparatus 150 of the modification mentioned above performs the battery cooling of the secondary battery 50, and demonstrates the process which memorize | stores generation | occurrence | production of battery cooling when needed.

14 and 15 show a flowchart of the battery cooling process (S250) performed by the air conditioning control device 150 according to the modification. When it is determined that the battery cooling is necessary in the air conditioning control process described with reference to FIGS. 3 and 4 (S117: yes in FIG. 4), this process is performed according to the above-described battery cooling process (S200). ) Is started instead of.
The battery cooling process (S250) of this modified example displays an image (see FIG. 13) indicating that the battery cooling is started with respect to the battery cooling process of the present embodiment described above with reference to FIGS. And the point that it is determined whether or not the confirmation button has been pressed between the time the image is displayed and the predetermined confirmation time elapses. Below, the battery cooling process of a modification is demonstrated easily centering on these differences.

As shown in FIG. 14, even in the case of the battery cooling process (S250) of the modified example, when the process is started, first, the current operating condition of the air conditioner 10 (the air conditioning operation is either the cooling operation or the heating operation). And the rotational speed Rc of the electric compressor 11) are stored (S251). Subsequently, it is determined whether or not the current air conditioning operation is a cooling operation (S252). When the air conditioning operation is a heating operation (S252: no), as described above with reference to FIG. The setting of the valve 13 and the three-way valve 17 is switched to the setting of the cooling operation state (S253).
Then, the battery cooling rotation speed is set as the target rotation speed Rm of the electric compressor 11 (S254).

Thereafter, in the battery cooling process of the modified example, after displaying an image (see FIG. 13) informing the start of battery cooling on the screen of the touch panel 2 (S259), a confirmation button displayed on the screen of the touch panel 2 is displayed. It is determined whether or not the button has been pressed (S260).
In addition, in the battery cooling process of a modification, although demonstrated as what displays the image illustrated in FIG. 13 on the screen of the touch panel 2, it should be able to alert | report generation | occurrence | production of battery cooling with respect to the passenger | crew of a vehicle. For example, the notification mode is not limited to display of an image. For example, you may alert | report by outputting a predetermined audio | voice from the speaker which is not shown in figure.

  As a result, if the confirmation button has not been pressed (S260: no), it is determined whether or not a predetermined confirmation time (for example, 5 seconds) has elapsed since the image was displayed on the screen of the touch panel 2 (S261). If the confirmation time has not elapsed (S261: no), it is determined again whether the confirmation button has been pressed (S260).

If such a determination is repeated, the confirmation button will eventually be pushed, or the confirmation time will elapse without the confirmation button being pushed. Therefore, when the confirmation time has elapsed (S261: yes), the battery cooling storage flag is set to ON (S262). As described above, the state in which the battery cooling storage flag is set to ON indicates that the occurrence of battery cooling is stored.
On the other hand, when the confirmation button is pressed before the confirmation time elapses (S260: yes), the battery cooling storage flag remains set to OFF. As described above, the state in which the battery cooling storage flag is set to OFF represents that the occurrence of battery cooling is not stored.
When the battery cooling memory flag is set in this manner, the battery cooling two-way valve 42 is opened and the cooling water pump 43 is driven (S263 in FIG. 15), and then the electric compressor 11 is driven at the target rotational speed Rm ( S264), thereby starting the battery cooling.

On the other hand, when the air-conditioning operation when the battery needs to be cooled is the cooling operation (S252 of FIG. 14: yes), the rotation speed Rc of the electric compressor 11 during the cooling operation is set to the battery cooling. The rotational speed is added (S255), and it is determined whether or not the obtained addition value is larger than the maximum rotational speed Rmax of the electric compressor 11 (S256).
As a result, when the added value is larger than the maximum rotation speed Rmax (S256: yes), the maximum rotation speed Rmax is set as the target rotation speed Rm of the electric compressor 11 (S257).

Subsequently, after displaying an image informing the start of battery cooling on the screen of the touch panel 2 (S259), it is determined whether or not the confirmation button displayed on the screen of the touch panel 2 has been pressed (S260), If the confirmation button has not been pressed (S260: no), it is determined whether or not a predetermined confirmation time (for example, 5 seconds) has elapsed since the image was displayed on the screen of the touch panel 2 (S261). In this way, the determination of S260 and S261 is repeated until the confirmation button is pressed (S260: yes) or until the confirmation time elapses without the confirmation button being pressed (S261: yes).
As a result, when the confirmation time has elapsed (S261: yes), the battery cooling storage flag is set to ON (S262). On the other hand, when the confirmation button is pressed before the confirmation time elapses (S260: yes), the battery cooling storage flag remains set to OFF. Thereafter, the battery cooling two-way valve 42 is opened and the cooling water pump 43 is driven (S263 in FIG. 15), and then the electric compressor 11 is driven at the target rotational speed Rm (S264), thereby cooling the battery. To start.

On the other hand, when the addition value obtained by adding the battery cooling rotation speed to the rotation speed Rc of the electric compressor 11 during the cooling operation is smaller than the maximum rotation speed Rmax (S256: no), the addition value is set to the electric compressor 11. Is set as the target rotational speed Rm (S258).
In this case, the battery cooling two-way valve 42 is opened and the cooling water pump 43 is displayed without displaying an image informing that the battery is cooled or setting the battery cooling memory flag to ON. Is driven (S263 in FIG. 15), the battery cooling of the secondary battery 50 is started by driving the electric compressor 11 at the target rotational speed Rm (S264).

In the subsequent processes, the battery cooling process of the modified example is the same as the battery cooling process of the present embodiment described above. That is, the battery cooling is continued until the battery temperature of the secondary battery 50 decreases to a predetermined target temperature, but when the battery temperature decreases to the target temperature (S265: yes), the battery cooling two-way valve 42 is closed. At the same time, the cooling water pump 43 is stopped (S266).
Then, the condition when the battery cooling occurs (that is, the battery cooling occurrence condition) is transmitted to the external server (S267), and if the battery cooling storage flag is set to ON (S268: yes), the battery Information indicating the occurrence of cooling is stored in a memory (not shown) of the air conditioning control device 100 (S269).
Thereafter, after the battery cooling memory flag is set to OFF (S270), the operation state of the air conditioner 10 is returned to the state before the battery cooling occurs (S271), and the battery of the modified example shown in FIGS. Finish the cooling process.

In the battery cooling process of the modified example described above, when battery cooling occurs during the heating operation (S252: no in FIG. 14), or when battery cooling occurs during the cooling operation at a high load (S256: yes). However, the occurrence of battery cooling is notified (S259). In response to the notification, when the confirmation button is pressed before the confirmation time elapses (S260: yes), the vehicle occupant is informed that battery cooling occurs or battery cooling occurs. Along with this, it may be considered that the air conditioning capacity is temporarily reduced. Accordingly, there is no possibility that a temporary malfunction of the air conditioning is misunderstood as an abnormality of the air conditioner 10 and brought into inspection and repair, so there is no need to store the occurrence of battery cooling.
On the other hand, if the confirmation button is not pressed even after the confirmation time has elapsed with respect to the display for informing the occurrence of battery cooling (S260: no), the occurrence of battery cooling has been informed. The vehicle occupant may not be aware. Therefore, in this case, there is a possibility that a temporary malfunction of the air conditioning is misunderstood as an abnormality of the air conditioner 10 and brought into inspection and repair. Therefore, it is necessary to store the occurrence of battery cooling. Therefore, the battery cooling storage flag is set to ON (S262), and the occurrence of battery cooling is stored in the memory (S269 in FIG. 15).

Thus, in the air conditioning control device 150 of the modified example, even when the battery cooling occurs when the air conditioning device 10 performs the heating operation or when the battery cooling occurs during the cooling operation at a high load, the battery cooling is performed. If the vehicle occupant notices the occurrence of this, the occurrence of battery cooling is not stored. For this reason, the number of times of occurrence of battery cooling is reduced, and the memory capacity required for storage can be saved.
In addition, since the battery occupant is informed of the occurrence of battery cooling, understanding of battery cooling gradually proceeds. As a result, even if temporary air conditioning malfunction occurs due to the occurrence of battery cooling, it is possible to reduce the situation that the air conditioner 10 is mistaken for an abnormality and brought into inspection and repair.

  As mentioned above, although the present Example and the modification were demonstrated, this invention is not restricted to said Example and a modification, It can implement in a various aspect in the range which does not deviate from the summary.

1 ... air conditioning system, 2 ... touch panel, 8 ... wireless communication device,
10 ... Air conditioner, 11 ... Electric compressor, 12 ... Indoor condenser,
13 ... Two-way valve for cooling, 14 ... First expansion valve, 15 ... Outdoor condenser,
16 ... second expansion valve, 17 ... three-way valve, 18 ... evaporator,
19 ... Accumulator, 40 ... Battery cooling device, 41 ... Heat exchanger for battery cooling,
42 ... Two-way valve for battery cooling, 43 ... Cooling water pump, 44 ... Refrigerant piping for battery cooling,
45 ... Cooling water piping, 50 ... Secondary battery, 50s ... Battery temperature sensor,
DESCRIPTION OF SYMBOLS 100 ... Air-conditioning control apparatus, 101 ... Air-conditioning operation | movement acquisition part, 102 ... Target temperature acquisition part,
103 ... Indoor temperature acquisition unit, 104 ... Outdoor temperature acquisition unit, 105 ... Solar radiation amount acquisition unit,
106: Operating state control unit, 107 ... Battery temperature acquisition unit, 108 ... Cooling necessity determination unit,
109 ... battery cooling unit, 110 ... running state acquisition unit, 111 ... cooling condition collection unit,
112 ... Cooling generation storage unit, 113 ... Confirmation request output unit, 114 ... Confirmation operation detection unit,
150: Air conditioning control device.

Claims (10)

A vehicle including an air conditioner (10) that adjusts an air temperature in a passenger compartment using a temperature change when the refrigerant gas compressed by the compressor (11) is decompressed and expanded, and a secondary battery (50). An air conditioning control device (100, 150) that controls the operation of the air conditioning device,
An indoor temperature acquisition unit (103) for acquiring the indoor temperature of the vehicle interior;
A target temperature acquisition unit (102) for acquiring a target temperature set for the room temperature;
An operation state control unit (106) for controlling an operation state of the air conditioner based on the indoor temperature and the target temperature;
A battery temperature acquisition unit (107) for acquiring a battery temperature of the secondary battery;
A cooling necessity judgment unit (108) for judging whether or not the secondary battery needs to be cooled based on the battery temperature;
When the battery cooling is required, a battery cooling unit (109) for cooling the secondary battery using a temperature change of the refrigerant gas;
When cooling the battery, it is determined whether or not the operating state of the air conditioner satisfies a predetermined condition, and if the predetermined condition is satisfied, a cooling generation storage unit (112) that stores the generation of the battery cooling And an air conditioning control device. The air conditioning control device according to claim 1,
The operation state control unit can be controlled as an operation state of the air conditioner to a cooling operation state in which the temperature of the refrigerant gas is reduced when the decompression expansion is performed, and the indoor temperature is lowered.
The cooling generation storage unit stores the generation of the battery cooling assuming that the operation state corresponds to the predetermined condition when the battery cooling occurs during the cooling operation operation state. Control device. The air conditioning control device according to claim 2,
The operation state control unit also determines the cooling capacity generated by the air conditioner as the operation state of the air conditioner in the cooling operation state.
The cooling generation storage unit is configured such that when the cooling capacity generated by the air conditioner is less than a predetermined amount with respect to the maximum cooling capacity of the air conditioner, the operation state corresponds to the predetermined condition. An air conditioning control device that memorizes the occurrence of battery cooling. The air conditioning control device according to claim 3,
The operating state control unit determines the rotational speed of the compressor as the cooling capacity of the air conditioner,
The cooling generation storage unit determines that the operation state corresponds to the predetermined condition when the margin of the rotation speed of the compressor with respect to the maximum rotation speed of the compressor is a predetermined amount or less. An air-conditioning control device characterized by memorizing the occurrence of air. It is an air-conditioning control device according to any one of claims 1 to 4,
The operation state control unit absorbs heat from the air outside the passenger compartment using the temperature decrease of the refrigerant gas when the decompression expansion is performed, and then compresses the absorbed refrigerant gas as the operation state of the air conditioner. It is controllable to a heating operation state in which the room temperature is raised by utilizing a temperature rise when compressed by a machine,
The cooling generation storage unit stores the generation of the battery cooling, assuming that the operation state corresponds to the predetermined condition when the battery cooling occurs during the heating operation state. Control device. An air conditioning control device (150) according to any one of claims 1 to 5,
A confirmation request output unit (113) for outputting a request for a confirmation operation to the driver of the vehicle when the secondary battery is cooled by a battery;
A confirmation operation detection unit (114) for detecting the confirmation operation for the request, and
The cooling generation storage unit stores the generation of the battery cooling when the operation state of the air conditioner satisfies the predetermined condition and the confirmation operation is not detected in response to the request for the confirmation operation. An air conditioning control device characterized by that. It is an air-conditioning control device according to any one of claims 1 to 6,
The cooling generation storage unit stores information including a date when the battery cooling occurs. The air conditioning control device according to claim 7,
The cooling generation storage unit stores information including a date when the battery cooling occurs and an operation state of the air conditioner. The air conditioning control device according to any one of claims 1 to 8,
A traveling state acquisition unit (110) for acquiring the traveling state of the vehicle;
An air conditioning control device comprising: a cooling condition collection unit (111) that acquires information including a traveling state of the vehicle as a battery cooling generation condition and transmits the information to the outside of the vehicle when the battery cooling occurs. A vehicle including an air conditioner (10) that adjusts an air temperature in a passenger compartment using a temperature change when the refrigerant gas compressed by the compressor (11) is decompressed and expanded, and a secondary battery (50). Applied to the air conditioning control method for controlling the operation of the air conditioner,
Obtaining a room temperature in the vehicle compartment (S102);
Obtaining a target temperature set for the room temperature (S101);
A step (S105 to S115) of controlling an operating state of the air conditioner based on the room temperature and the target temperature;
Obtaining a battery temperature of the secondary battery (S116);
Determining whether or not the secondary battery needs to be cooled based on the battery temperature (S117);
If the battery needs to be cooled, the secondary battery is cooled using the temperature change of the refrigerant gas (S211, S264);
A step (S202, S206, S252, S256) of determining whether or not the operating state of the air conditioner corresponds to a predetermined condition when cooling the battery;
A step (S216, S269) of storing the generation of the battery cooling when the predetermined condition is met.

Images