JP4252172B2 - Battery cooling system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a battery cooling device.
[0002]
[Prior art]
In recent years, electric vehicles and hybrid vehicles have attracted attention because of energy saving and environmental considerations. Since electric vehicles and hybrid vehicles use a large number of batteries as power sources, the performance of the batteries is important. In order for the battery to fully perform and maintain its performance, it is necessary to adjust the temperature of the battery to an appropriate temperature. In particular, the battery needs to be cooled because it generates a lot of heat during charging or discharging and may become hot.
[0003]
Conventionally, the cooling of the battery is often by natural air cooling, but there are cases where it is not sufficient. Therefore, as described in Japanese Patent Application Laid-Open No. 7-6796, the bottom wall of the case for storing the battery and the partition between the batteries There is a hollow wall with a refrigerant pipe inserted to cool the battery by the refrigeration cycle, and the battery temperature is monitored so that the battery can be used under temperature conditions that do not shorten the service life. It has been proposed to control.
[0004]
[Problems to be solved by the invention]
By the way, when the circulation of the refrigerant fluid is controlled by monitoring the battery temperature, the circulation and suspension of the refrigerant fluid are repeated depending on the battery temperature. However, if the frequency is high, power is wasted and the efficiency is not good. For example, an internal combustion engine or the like, which is a power source for a compressor constituting the refrigeration cycle, is repeatedly started and stopped, and fuel efficiency is impaired.
[0005]
The present invention has been made in view of the above circumstances, and an object thereof is to provide a battery cooling device with good cooling efficiency.
[0006]
[Means for Solving the Problems]
According to the first aspect of the present invention, a compressor that makes the refrigerant high temperature and high pressure, a condenser that liquefies the high temperature and high pressure refrigerant, an expansion valve that expands the liquefied refrigerant and lowers the refrigerant temperature, a low temperature refrigerant sent from the expansion valve, and a battery And a battery cooler that cools the battery by heat exchange with the refrigeration cycle that recirculates the evaporated refrigerant of the cooler to the compressor. And a battery temperature detecting means for detecting the temperature of the battery, a switching means for switching supply and stop of the low-temperature refrigerant to the battery cooler, and a battery temperature detected by controlling the switching means is preset. When the temperature falls below the lower limit value, the flow of the low-temperature refrigerant in the battery cooler is stopped, and when the detected battery temperature exceeds the preset upper limit value, control means for causing the battery cooler to flow the low-temperature refrigerant is provided.
[0007]
Battery cooling is started when the battery temperature reaches the upper limit temperature and is performed until the battery temperature falls to the lower limit temperature. As a result, the battery is provided with a cold storage amount defined by a temperature difference between the upper limit temperature and the lower limit temperature. Until the battery temperature reaches the upper limit temperature in accordance with the amount of cold storage, cooling by the battery cooler is unnecessary, and the frequency of starting the compressor is reduced, and the cooling efficiency is improved. Therefore, battery cooling can be performed with low fuel consumption.
[0008]
Claim 1 In the described invention, further, An evaporator for indoor air conditioning is connected to the refrigeration cycle in parallel with the battery cooler, and the switching means is provided with valve means for switching the flow path of the low-temperature refrigerant to either the battery cooler or the evaporator.
[0009]
The refrigeration cycle can be used for both battery cooling and air conditioning.
[0010]
Claim 1 In the described invention, in addition, Air temperature detecting means for detecting the temperature of the air after heat exchange with the evaporator is provided, and the control means is used for controlling the low-temperature refrigerant until the detected air temperature is equal to or higher than a preset upper temperature during indoor air conditioning. Is set to flow through the battery cooler.
[0011]
Since the battery cooler cools the battery using the period when the air temperature has not reached the upper limit temperature and the evaporator is recognized to have at least the minimum cooling capacity, the frequency of starting the compressor is further reduced. Cooling efficiency is improved. Therefore, further battery cooling can be achieved with low fuel consumption.
[0012]
Claim 2 In the described invention, the compressor is engine And is driven by the power of engine Operating state As at least engine speed Operating state detecting means for detecting the above, and the control means, Engine The driving state is Preset Predetermined It is in the engine speed range and it is a low fuel consumption range with good battery cooling. High efficiency Operating range It is in In the high-efficiency operating range When the detected battery temperature does not exceed the upper limit temperature, the low-temperature refrigerant is set to flow through the battery cooler.
[0013]
Even if the battery temperature does not exceed the upper limit temperature, the battery cooler is operated in the high-efficiency region to replenish the cold storage amount of the battery, so that the battery can be further cooled with low fuel consumption.
[0014]
Claim 3 In the described invention, the control means is the high efficiency. operation During the flow control of the low-temperature refrigerant to the battery cooler in the region, the lower limit temperature is set to be switched to another set value on the low temperature side.
[0015]
Lowering the lower limit temperature increases the cold storage amount of the battery. Since the replenishment of the cold storage amount is performed with low fuel consumption, the battery can be further cooled with low fuel consumption.
[0016]
Claim 4 In the described invention, the refrigerant state detecting means for detecting the temperature or pressure of the refrigerant flowing through the battery cooler is provided. The control means is set to prohibit the flow of the low-temperature refrigerant to the battery cooler when the temperature or pressure of the refrigerant is equal to or lower than the preset lower limit temperature or lower limit pressure.
[0017]
It is possible to prevent a decrease in cooling efficiency due to an excessive cooling capacity and an excessive cooling of a part of the battery due to a temperature difference between the battery temperature detection part and the cooling part.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 1 shows a battery cooling device according to a first embodiment of the present invention. The present embodiment is applied to a hybrid vehicle including an internal combustion engine (engine) 21 that operates with fuel as power and a motor 22 that operates with electricity. The battery cooling device includes a refrigeration cycle 1 for cooling the battery 6, and the refrigeration cycle 1 includes a compressor 11, a condenser 12, a receiver 13, an expansion valve 14a, a battery cooler 15a, and the like, which are in this order. The refrigerant pipes 100 are connected.
[0019]
The compressor 11 compresses the vaporized refrigerant to a high temperature and high pressure. The compressor 11 operates by driving the engine 21 and can be connected to and disconnected from the engine 21 by an electromagnetic clutch (hereinafter referred to as a clutch) 111. The condenser 12 dissipates the heat of the high-temperature and high-pressure refrigerant to the outside air supplied from the front of the vehicle to liquefy the high-temperature and high-pressure refrigerant. The receiver 13 performs gas-liquid separation of the refrigerant and stores excess liquefied refrigerant. The expansion valve 14a reduces the pressure of the liquefied refrigerant to low temperature and low pressure. The low-temperature and low-pressure refrigerant from the expansion valve 14a is used for cooling the battery 6 in the battery cooler 15a. As the refrigerant, carbon dioxide, propane, methane, ammonia, or the like can be used in addition to general chlorofluorocarbon.
[0020]
The compressor 11, the condenser 12, and the receiver 13 are also used as an air conditioner that cools the interior of the passenger compartment 8. That is, the refrigerant pipe 100 is branched downstream of the receiver 13, and another expansion valve 14b and an evaporator 15b are provided in parallel with the expansion valve 14a and the battery cooler 15a.
[0021]
In addition, the refrigerant pipe 100 is provided with two electromagnetic valves 3a and 3b. The electromagnetic valve 3a allows or prohibits the flow of refrigerant from the receiver 13 to the battery cooler 15a, and the electromagnetic valve 3b moves from the receiver 13 to the evaporator 15b. Allow or prohibit the flow of refrigerant. The electromagnetic valves 3a and 3b are controlled by the battery cooling ECU 4a, and low temperature and low pressure liquefied refrigerant flows through either the battery cooler 15a or the evaporator 15b by switching the electromagnetic valves 3a and 3b. The circulation and stoppage of the liquefied refrigerant are performed by starting and stopping the engine 21 and connecting / disconnecting the engine 21 and the compressor 11 by the hybrid mechanism ECU 4c and the clutch 111 which constitute switching means together with the electromagnetic valves 3a and 3b. It is possible to switch by doing.
[0022]
The evaporator 15 b is provided in a duct 91 that opens into the passenger compartment 8. The duct 91 is provided with a blower fan 92 for blowing air on the upstream side, and supplies air that has been cooled by exchanging heat with the evaporator 15 b into the passenger compartment 8. The air taken in by the blower fan 92 is selected between inside air and outside air by switching the damper 93.
[0023]
The battery cooler 15 a is stored in the heat insulating case 7 together with the battery 6. An air layer S is formed between the heat insulating case 7, the battery cooler 15a, and the battery 6 to further enhance the heat insulating property. The reciprocation of the refrigerant to the battery cooler 15 a is performed through the joint portion 101 of the refrigerant pipe 100 attached to the outer wall surface of the heat insulating case 7.
[0024]
The battery cooler 15a includes a base 151 and a plurality of heat transfer fins 152 standing in a partition shape from the base 151, and a fin tube 153 is inserted into the base 151. The fin tube 153 forms an intermediate part of the refrigerant pipe 100. One end of the fin tube 153 communicates with the expansion valve 14a and the other end communicates with the compressor 11. The low-temperature refrigerant from the expansion valve 14a flows therethrough.
[0025]
One battery 6 is disposed between two adjacent heat transfer fins 152, and the side surfaces of the batteries 6 are in close contact with the main surface of the heat transfer fins 152 to enhance heat transfer. The low-temperature refrigerant flowing through the fin tube 153 exchanges heat with the battery 6 through the tube wall, the base 151 and the heat transfer fins 152 to cool the battery 6.
[0026]
In addition to the battery cooling ECU 4a, the air conditioner ECU 4b and the hybrid mechanism ECU 4c are provided for the control of the above parts. The three ECUs 4a to 4c communicate with each other to transmit and receive information and command signals necessary for control. Yes. Each ECU 4a-4c is comprised by the microcomputer etc. provided with CPU, memory, etc., for example.
[0027]
Various sensors 51, 52, 53, 54, and 55 are provided in each part of the apparatus to obtain the control information. As a sensor for outputting a signal to the battery cooling ECU 4a, a temperature sensor 51 is provided on the surface of the battery 6 so as to detect the battery temperature Tb. A temperature sensor 52 is provided in the vicinity of the evaporator 15b in the vicinity of the evaporator 15b so as to detect the air temperature (hereinafter referred to as the outlet temperature) Tc after heat exchange with the evaporator 15b. As a sensor that outputs a signal to the air conditioner ECU 4b, a sunshine sensor 53 for knowing the passenger's indoor environment is provided. In addition, an air conditioner operation panel 401 is attached in the passenger compartment 8, and a passenger operates to transmit a predetermined indoor air conditioning command to the air conditioner ECU 4b by a switch operation. A throttle sensor 54 is provided as a sensor for outputting a signal to the hybrid mechanism ECU 4c, and detects the throttle opening. An engine speed sensor 55 is provided to detect the engine speed. These throttle opening and engine speed are used for vehicle travel control.
[0028]
The operation of the battery cooling apparatus will be described with reference to the setting of the battery cooling ECU 4a as the control means, with reference to FIGS. In FIG. 2, when the control is started (step S100), the battery temperature Tb is detected in step S110, and it is determined whether or not the battery temperature Tb is equal to or higher than the upper limit temperature TbH1 in step S120. Here, the upper limit temperature TbH1 is set in consideration of the life of the battery 6 (for example, 40 ° C.). If step S120 is negative, that is, if the battery temperature Tb is equal to or lower than the upper limit temperature TbH1, this control is terminated (step S130).
[0029]
If step S120 is positive, that is, if the battery temperature Tb is equal to or higher than the upper limit temperature TbH1, it is determined that the battery 6 needs to be cooled, and the steps after step S140 are executed. In step S140, it is determined based on the operating state of the compressor 11 whether or not the air conditioning is in operation. This information is obtained from the air conditioner ECU 4b by inter-ECU communication. If the air conditioning operation is not being performed, the procedure after step S150 shown in FIG. 3 is executed, and if the air conditioning operation is being executed, the procedure after step S260 shown in FIG. 4 is executed.
[0030]
(Without air conditioning operation)
In FIG. 3, it is determined in step S150 whether or not the engine 21 is operating. This information is obtained from the hybrid mechanism ECU 4c by communication between the ECUs 4a to 4c. If the engine 21 is not operating, a command signal is transmitted to the hybrid mechanism ECU 4c in step S160 to start (turn on) the engine 21, and the process proceeds to step S170. If the engine 21 is operating, the process proceeds directly to step S170.
[0031]
In step S170, it is determined whether or not the clutch 111 is engaged. If the clutch 111 is not engaged, the clutch is turned on in step S180 and the process proceeds to step S190. If the clutch 111 is engaged, the process proceeds to step S190. In step S190, the electromagnetic valve 3a (hereinafter referred to as electromagnetic valve Vb) is turned on and opened, and the electromagnetic valve 3b (hereinafter referred to as electromagnetic valve Vc) is turned off and closed. Thereby, a low temperature (for example, 0 degreeC) refrigerant | coolant is supplied to the battery cooler 15a, and the battery 6 is cooled.
[0032]
In subsequent step S200, the battery temperature Tb is detected, and in step S210, it is determined whether or not the battery temperature Tb is equal to or lower than the lower limit temperature TbL. Here, the lower limit temperature TbL is a temperature at which it is determined that cooling is not necessary. The lower limit temperature TbL is set in consideration of the fact that the amount of cold storage of the battery 6 is specified and the lower the temperature, the lower the temperature. ).
[0033]
If the battery temperature Tb is equal to or higher than the lower limit temperature TbL, the process proceeds to step S220 to determine whether air conditioning is necessary. This information is obtained from the air conditioner ECU 4b by inter-ECU communication. If air conditioning is not required, the process returns to step S200. That is, as long as there is no request for air conditioning and the battery temperature Tb is equal to or higher than the lower limit temperature TbL, steps S200 to S220 are repeated, and the cooling of the battery 6 is continued and the battery temperature Tb decreases.
[0034]
When the battery temperature Tb becomes equal to or lower than the lower limit temperature TbL (step S210), it is determined that the battery 6 has reached the specified cold storage amount, and the battery cooling operation end control is performed in steps S230 to S250.
[0035]
In step S230, it is first determined whether it is necessary to continue the operation of the engine 21 or whether air conditioning is necessary. If neither the engine operation nor the air conditioning is necessary, the engine 21 is stopped (turned off) and the clutch 111 is turned on in step S240. Is turned off, the flow of the low-temperature refrigerant in the battery cooler 15a is stopped, and the cooling of the battery 6 is finished. Next, in step S250, the solenoid valve Vb is turned off and the solenoid valve Vc is turned on, and the process returns to step S110. After the cooling of the battery 6 is stopped, the temperature Tb rises due to heat generation or the like, but steps S110 to S130 are repeated unless the upper limit temperature TbH1 is exceeded. During this time, the engine 21 is turned on to cool the battery 6. The clutch 111 is never turned on.
[0036]
(With air conditioning operation)
When it is determined in step S140 that the air conditioning operation is being performed, the procedure in the case where it is determined in step S220 that air conditioning is necessary will be described with reference to FIG. This is a control mode aimed at air conditioning as the battery 6 is cooled.
[0037]
In step S260, the battery temperature Tb is detected, and in step S270, it is determined whether or not the battery temperature Tb is equal to or higher than the maximum upper limit temperature TbH3. The maximum upper limit temperature TbH3 is an upper limit temperature for avoiding an excessive increase in the battery temperature Tb, and is set in consideration of a temperature that may cause damage to the battery 6 if the temperature is further increased (for example, 55 ° C.).
[0038]
Therefore, if the battery temperature Tb is equal to or higher than the maximum upper limit temperature TbH3 in step S270, steps S280 to S300 are executed to stop or hold the air conditioning for the time being and to cool the battery 6 to prevent the battery temperature Tb from rising excessively. That is, first, in step S280, the electromagnetic valve Vb is turned on and the electromagnetic valve Vc is turned off to allow the low-temperature refrigerant to flow through the battery cooler 15a. Next, in step S290, the battery temperature Tb is detected, and in step S300, it is determined whether or not the battery temperature Tb is equal to or lower than the upper limit temperature TbH1. If the battery temperature Tb is equal to or higher than the upper limit temperature TbH1, the process returns to step S290 and steps S290 and S300 are repeated. Thus, only the cooling of the battery 6 is performed with the highest priority until the battery temperature Tb becomes equal to or lower than the upper limit temperature TbH1.
[0039]
When the battery temperature Tb becomes equal to or lower than the upper limit temperature TbH1 in step S300, the process proceeds to step S310. Steps S <b> 310 to S <b> 410 are procedures for performing air conditioning while cooling the battery 6.
[0040]
First, in step S310, the outlet temperature Tc is detected, and in step S320, it is determined whether or not the outlet temperature Tc is equal to or higher than the upper limit temperature TcH. Here, the outlet upper limit temperature TcH is set to, for example, 10 ° C. at a temperature at which the evaporator 15b can be regarded as holding the minimum cooling capacity.
[0041]
If the outlet temperature Tc is equal to or lower than the upper limit temperature TcH in step S320, it is determined that the cooling capacity is sufficient, and in step S330, the electromagnetic valve Vb is turned on and the electromagnetic valve Vc is turned off to distribute the low-temperature refrigerant to the battery cooler 15a. Let me. Next, in step S340, the battery temperature Tb is detected, and in step S350, it is determined whether or not the battery temperature Tb is lower than the lower limit temperature TbL. If the battery temperature Tb is equal to or higher than the lower limit temperature TbL, it is determined that the predetermined cold storage amount TbH1-TbL has not been reached, and the process returns to step S310. That is, as long as the outlet temperature Tc is not more than the upper limit temperature TcH (step S320) and at least the minimum cooling capacity is maintained, if the battery temperature Tb is not less than the lower limit temperature TbL (step S350), steps S310 to S350 are repeated. The cooling of the battery 6 is prioritized.
[0042]
Next, a case where air conditioning is prioritized will be described. If the outlet temperature Tc is equal to or higher than the upper limit temperature TcH in step S320, it is determined that the cooling capacity is not sufficient and air conditioning is prioritized. That is, in step S380, the electromagnetic valve Vb is turned off and the electromagnetic valve Vc is turned on to stop the flow of the low-temperature refrigerant in the battery cooler 15a and to flow the low-temperature refrigerant to the evaporator 15b. In subsequent step S390, the outlet temperature Tc is detected, and in step S400, it is determined whether or not the outlet temperature Tc is equal to or higher than the lower limit temperature TcL. Here, the outlet lower limit temperature TcL is a temperature at which the evaporator 15b can be considered to have sufficient cooling capacity, and is set to 5 ° C., for example.
[0043]
If the outlet temperature Tc is equal to or higher than the lower limit temperature TcL in step S400, it is determined that the predetermined cooling capacity has not been reached. In step S410, the battery temperature Tb is detected. In step S420, the battery temperature Tb is equal to or higher than the upper limit temperature TbH1. Determine whether or not. If the battery temperature Tb is equal to or lower than the upper limit temperature TbH1, it is determined that the battery 6 still has a cold storage amount, and the process returns to step S390. That is, while the battery temperature Tb is equal to or lower than the upper limit temperature TbH1 (step S420) and at least the amount of cold storage remains, if the outlet temperature Tc is equal to or higher than the lower limit temperature TcL (step S400), steps S390 to S420 are repeated and air conditioning has priority. Is done.
[0044]
When the outlet temperature Tc becomes equal to or lower than the lower limit temperature TcL (step S400), it is determined that the cooling capacity of the evaporator 15b is sufficient, the process proceeds to step S330 and the electromagnetic valve Vb is turned on and the electromagnetic valve Vc is turned off. To the battery cooler 15a.
[0045]
As described above, if the outlet temperature Tc is not equal to or higher than the upper limit temperature TcH, the battery 6 is stored cold until the battery temperature Tb becomes equal to or lower than the lower limit temperature TbL (steps S320, S330, S350). If it is not higher than the upper limit temperature TbH1, the ability of the evaporator 15b is increased until the outlet temperature Tc becomes lower than the lower limit temperature TcL (steps S380, S400, S420). This is because the battery 6 is cold-accumulated during the period when the compressor 11 is turned off in the conventional outlet temperature Tc control, so that the engine 21 and the clutch 111 are turned on only a little. The battery 6 is efficiently used for cooling and air conditioning.
[0046]
When battery temperature Tb becomes lower than lower limit temperature TbL (step S350), it is determined whether engine operation or air conditioning is necessary in step S360. If neither is necessary, engine 21 is turned off in step S370. The clutch 111 is turned off, and the process returns to step S110.
[0047]
When the battery temperature Tb becomes equal to or higher than the upper limit temperature TbH1 (step S420), the process returns to step S260, and the procedure after step S260 is repeated.
[0048]
5 and 6 are time charts showing the operation of each part of the battery cooling device. FIG. 5 shows the case where only the cooling of the battery 6 is performed and the control shown in FIG. 3 is performed. This is a case where the control of FIG. 4 is performed in both cases of air conditioning.
[0049]
In FIG. 5, at the initial stage, the battery temperature Tb gradually increases due to heat generation of the battery 6 but is not higher than the upper limit temperature TbH1, so that the compressor 11 is not operated and the solenoid valves Vb and Vc are off. is there.
[0050]
When the battery temperature Tb becomes equal to or higher than the upper limit temperature TbH1, when the engine 21 is off, the engine 21 is turned on and the clutch 111 is turned on. When the engine 21 is turned on, the compressor 11 is activated and the electromagnetic valve Vb is turned on. The low temperature refrigerant starts to flow into the battery cooler 15a and the battery 6 is cooled. As a result, the battery temperature Tb gradually decreases and finally becomes lower than the lower limit temperature TbL. Then, the engine 21, the clutch 111, and the electromagnetic valve Vb are restored to the original state (off). The battery temperature Tb rises again toward the upper limit temperature TbH1 due to its heat generation or the like. However, since the battery 6 is stored cold by the amount of TbH1−TbL, it is not necessary to cool immediately, and the battery 6 depends on the amount of cold stored in the battery 6. The on / off switching frequency of the engine 21 and the clutch 111 can be reduced.
[0051]
In FIG. 6, at the initial stage, the compressor 11 is operated, the electromagnetic valve Vb is turned off, the electromagnetic valve Vc is turned on, and the air conditioning is activated. As the clutch 111 is turned on / off, the outlet temperature Tc changes between the lower limit temperature TcL and the upper limit temperature TcH. The battery temperature Tb rises in the same manner as in FIG. 5, but the battery 6 is not cooled because it is not higher than the upper limit temperature TbH1.
[0052]
When the battery temperature Tb becomes equal to or higher than the upper limit temperature TbH1, the control proceeds to the control shown in FIG. 3. When the outlet temperature Tc is not equal to or higher than the upper limit temperature TcH, the electromagnetic valve Vc is turned off and the electromagnetic valve Vb is turned on. The low temperature refrigerant begins to flow into the vessel 15a, and the battery 6 is cooled. As a result, the battery temperature Tb gradually decreases, but the outlet temperature Tc gradually increases due to heat exchange with the air flowing in the duct 91.
[0053]
When the outlet temperature Tc becomes equal to or higher than the upper limit temperature TcH, the solenoid valve Vb is turned off and the solenoid valve Vc is turned on to increase the cooling capacity of the evaporator 15b, and a low-temperature refrigerant is allowed to flow through the evaporator 15b to lower the outlet temperature Tc. Let During this time, the battery temperature Tb rises again, but when the outlet temperature Tc falls below the lower limit temperature TcL, the solenoid valve Vc is turned off and the solenoid valve Vb is turned on to restart the cooling of the battery 6 and the battery temperature Tb is reduced to its lower limit temperature. Decreases toward TbL. If the battery temperature Tb becomes equal to or lower than the lower limit temperature TbL, only air conditioning is performed as before the start of battery cooling.
[0054]
As is known from the operating state of the compressor 11 at the time when only air conditioning is performed and the operating state of the period during which air conditioning and battery cooling are being performed, the period during which the compressor 11 is turned off using only air conditioning is utilized. Since the low-temperature refrigerant from the refrigeration cycle 1 flows into the battery cooler 15a and is stored in the battery 6, the on / off switching frequency of the engine 21 and the clutch 111 can be reduced according to the amount of cold storage in the battery 6, and the fuel efficiency can be reduced. Good battery 6 cooling is possible.
[0055]
(Second Embodiment)
In this embodiment, a part of the control in the battery cooling ECU 4a is changed in the configuration of the first embodiment, and the difference in control will be mainly described. The battery cooling ECU 4a has an engine operation state map stored in its memory, and the engine operation state based on the throttle opening and the engine speed known from the throttle sensor 54, which is an operation state detection means, and the engine speed sensor 55. Is detected. The engine operating state map is a high-efficiency operating range when the engine speed is in a predetermined engine speed range. Classified as binary. The engine operation state map is set in advance in consideration of the characteristics of the engine 21 and the compressor 11, and different maps are given according to the throttle opening. This is because when the throttle opening is large, the pumping loss of the engine is small, and it is determined that the operating range is high efficiency. The throttle opening and the engine speed are obtained from the hybrid mechanism ECU 4c through the above-mentioned communication between ECUs.
[0056]
The battery cooling ECU 4a executes the control shown in FIG. 7 and the same control as the control in FIGS. 3 and 4 of the first embodiment. In FIG. 7, in the first embodiment, the battery 6 is cooled only when the battery temperature Tb is equal to or higher than the upper limit temperature TbH1 (see FIG. 2). However, the battery temperature Tb is equal to or higher than the upper limit temperature TbH1. If not (step S120), it is determined in step S121 whether the battery temperature Tb is equal to or higher than the lower limit temperature TbL. If the battery temperature Tb is equal to or higher than the lower limit temperature TbL, the engine operating state is detected in step S122, and it is determined in step S123 whether the engine operating state is in a high efficiency operating range.
[0057]
In the high-efficiency operation region, even if the battery temperature Tb is not equal to or higher than the upper limit temperature TbH1, the process proceeds to step S140 as in the case where the battery temperature Tb is equal to or higher than the upper limit temperature TbH1. The battery 6 is cooled so that the battery temperature Tb falls to the lower limit temperature TbL (see step S190 in FIG. 3 and step S330 in FIG. 4). As described above, when the engine operating state is in the high-efficiency operation region, the battery 6 is cooled even if the battery temperature Tb is not equal to or higher than the upper limit temperature TbH1, and the regenerative amount is replenished, so that the engine efficiency is good. Therefore, battery cooling can be performed with lower fuel consumption.
[0058]
If the battery temperature Tb is equal to or lower than the lower limit temperature TbL in step S121, this control is terminated. This is because the cold storage amount of the battery 6 is sufficient.
[0059]
Further, the present control is also terminated when the engine operating state is not in the high efficiency operating range in step S123. This is because there is not enough fuel efficiency.
[0060]
In the present embodiment, whether or not the engine operating state is the high efficiency operating state is determined based on the throttle opening and the engine speed. ,other You may judge by adding the item of. Alternatively, it may be determined simply based on the engine speed.
[0061]
(Third embodiment)
In this embodiment, a part of the setting of the battery cooling ECU is changed in the configuration of the second embodiment, and the difference from the second embodiment will be mainly described.
[0062]
In the battery cooling ECU 4a, the control shown in FIG. 8 and the same control as the control in FIGS. 3 and 4 of the first embodiment are executed. In FIG. 8, in the second embodiment, when the battery temperature Tb is not equal to or higher than the upper limit temperature TbH1 and the battery temperature Tb is equal to or higher than the lower limit temperature TbL (steps S120 and S121 in FIG. 7), the engine operating state is in the high efficiency operating range. If there is, the battery 6 is cooled. In this embodiment, it is determined in step S121A in place of step S121 whether the battery temperature Tb is equal to or higher than the lower limit temperature TbL2, and the battery temperature Tb is higher than the upper limit temperature. When the battery temperature Tb is not lower than TbH1 (step S120) and the lower limit temperature TbL2 is higher than the lower limit temperature TbL2, the battery is cooled if the engine operating state is in the high efficiency operating range (step S123). The lower limit temperature TbL2 is set to a temperature (for example, 20 ° C.) lower than the lower limit temperature TbL.
[0063]
In the high-efficiency operation region, that is, when step S123 is affirmed, the battery temperature (step S210 in FIG. 3 and S350 in FIG. 4) serving as a reference for stopping the cooling operation of the battery 6 is the lower limit temperature TbL2. .
[0064]
Thereby, the cold storage amount in the battery 6 increases as TbH1−TbL2, and the battery 6 can be cooled with low fuel consumption.
[0065]
(Fourth embodiment)
FIG. 9 shows the configuration of the battery cooling device according to the present embodiment. In the first embodiment, the refrigeration cycle is operated by a motor 23 for driving the compressor instead of the internal combustion engine. In the battery cooling ECU 4a, the same control as the control of FIG. 2 of the first embodiment, and the control shown in FIGS. 10 and 11 are executed. The control in FIGS. 10 and 11 is basically the same as the control in FIGS. 3 and 4 of the first embodiment, and the difference from the first embodiment will be mainly described.
[0066]
In FIG. 10, in place of steps S150 to S180 of the first embodiment, in this embodiment, the compressor motor 23 is turned on and the refrigeration cycle 1 is operated in step 150A.
[0067]
In this embodiment, in place of steps S230 and S240 in the first embodiment, it is determined whether or not air conditioning is necessary in step 230A. If air conditioning is not necessary, the compressor motor 23 is turned off in step 240A. If air conditioning is necessary, the process returns to step S110 (FIG. 2).
[0068]
In FIG. 11, instead of steps S360 and S370 of the first embodiment, in this embodiment, it is determined whether or not air conditioning is necessary in step S360A. If air conditioning is not necessary, the compressor motor 23 is turned off in step S370A. If air conditioning is necessary, the process returns to step S110 (FIG. 2).
[0069]
(Fifth embodiment)
This embodiment uses a variable capacity compressor as the compressor 11 in the first embodiment, and the battery cooling ECU 4a executes the same control as the control of FIG. 2 of the first embodiment, and the control shown in FIGS. Is done. The control in FIGS. 12 and 13 is basically the same as the control in FIGS. 3 and 4 of the first embodiment, and the difference from the first embodiment will be mainly described.
[0070]
In FIG. 12, instead of steps S170 and S180 of the first embodiment, in this embodiment, the compressor capacity Cv is set to Cv1 and the refrigeration cycle is operated in step S170B. The capacity Cv1 may be set to the maximum capacity of the compressor 11 giving priority to the battery cooling capacity, or may be limited to a value lower than the maximum capacity in consideration of uneven temperature of the battery 6.
[0071]
In this embodiment, the engine 21 is turned off in step S240B instead of step S240 in the first embodiment.
[0072]
In FIG. 13, when the battery temperature Tb becomes equal to or higher than the maximum upper limit temperature TbH3 (step S270), the compressor capacity Cv is maximized in step S271 before the solenoid valve Vb is turned on and the solenoid valve Vc is turned off (step S280). Set. As a result, the battery 6 is protected by promptly avoiding an excessive increase in the battery temperature TbH3.
[0073]
In this embodiment, the engine 21 is turned off in step S370B instead of step S370 in the first embodiment.
[0074]
In this way, the present invention can be applied to a configuration using a variable compressor, and high cooling efficiency can be obtained.
[0075]
(Sixth embodiment)
FIG. 14 shows the configuration of the battery cooling device according to the present embodiment. The present embodiment is provided with a temperature sensor 56 which is a refrigerant state detecting means for detecting the temperature of the low-temperature and low-pressure refrigerant flowing into the battery cooler 15a in the first embodiment, and the battery cooling ECU 4a is the same as that of the first embodiment. The control shown in FIGS. 2 and 4 is executed, and the control shown in FIG. 15 is executed instead of the control shown in FIG.
[0076]
In FIG. 15, when it is determined that air conditioning is not necessary (step S220), the refrigerant temperature is detected in step S500, and in step S501, it is determined whether or not the detected refrigerant temperature Tr is equal to or lower than the lower limit temperature TrL. The lower limit temperature TrL is set to a temperature at which it is recognized that the cooling capacity of the battery 6 may become excessive, for example, −10 ° C. If the refrigerant temperature Tr is equal to or lower than the lower limit temperature TrL, it is determined that the cooling capacity is excessive. Then, the clutch 111 is turned off to prohibit the cooling of the battery 6, and the process returns to step S200.
[0077]
If the refrigerant temperature Tr is not less than the lower limit temperature TrL in step S501, the process proceeds to step S503, and it is determined whether or not the refrigerant temperature Tr is not less than the predetermined temperature Tr0. The predetermined temperature Tr0 is set to a temperature slightly higher than the lower limit temperature TrL, for example, 0 ° C. If refrigerant temperature Tr is below predetermined temperature Tr0, it will return to Step S200. That is, if the clutch 111 is turned off and the battery cooling is prohibited (step S502), the state is maintained even if the refrigerant temperature Tr is equal to or higher than the lower limit temperature TrL. When the refrigerant temperature rises due to heat absorption from the battery 6 and the refrigerant temperature Tr becomes equal to or higher than the predetermined temperature Tr0 in step S503, it is determined that the state of excessive cooling capacity has been sufficiently removed, and the clutch 111 is turned on in step S504. If the clutch 111 is off, the process proceeds to step S505, where the clutch 111 is turned on and the process returns to step S200.
[0078]
This produces the following effects. If the engine rotational speed is high and the refrigerant flow rate is increased and the cooling capacity becomes excessive, there is a possibility that the cooling efficiency is lowered due to an increase in the differential pressure between the high and low pressures of the refrigerant. In addition, the temperature difference between the refrigerant and the battery 6 is so large that the actual temperature of the cooling portion is too low with respect to the temperature detected by the temperature sensor 51 that detects the temperature of the battery 6, and the battery 6 may be uneven in temperature. In the present embodiment, since the cooling of the battery 6 is prohibited when the refrigerant temperature Tr becomes equal to or lower than the lower limit temperature TrL, it is possible to prevent such a situation from occurring. In addition, even if the refrigerant temperature Tr is equal to or higher than the lower limit temperature TrL, the cooling of the battery 6 is not resumed if the temperature is equal to or lower than the predetermined temperature Tr0.
[0079]
Although the refrigerant temperature is detected in the present embodiment, a pressure sensor that detects the refrigerant pressure flowing into the battery cooler may be provided, and the control as shown in FIG. 15 may be executed in the battery cooling ECU. In this case, the refrigerant pressure is detected, and battery cooling is prohibited when the refrigerant pressure falls below a predetermined lower limit pressure (for example, 0.2 MPa), and slightly exceeds the predetermined lower limit pressure even if the refrigerant pressure is equal to or higher than the predetermined lower limit pressure. If the pressure value (for example, 0.29 MPa) or less is maintained, the clutch 111 is kept off. After the pressure value is exceeded, the clutch 111 is turned on again to restart the battery cooling.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a battery cooling device according to a first embodiment of the present invention.
FIG. 2 is a first flowchart showing control in a battery cooling ECU of the battery cooling device.
FIG. 3 is a second flowchart showing control in a battery cooling ECU of the battery cooling device.
FIG. 4 is a third flowchart showing control in a battery cooling ECU of the battery cooling device.
FIG. 5 is a first time chart showing the operation of the battery cooling device.
FIG. 6 is a second time chart showing the operation of the battery cooling device.
FIG. 7 is a flowchart showing control in a battery cooling ECU of a battery cooling device according to a second embodiment of the present invention.
FIG. 8 is a flowchart showing control in a battery cooling ECU of a battery cooling device according to a third embodiment of the present invention.
FIG. 9 is a configuration diagram of a battery cooling device according to a fourth embodiment of the present invention.
FIG. 10 is a first flowchart showing control in a battery cooling ECU of the battery cooling device.
FIG. 11 is a second flowchart showing control in the battery cooling ECU of the battery cooling device.
FIG. 12 is a first flowchart showing control in a battery cooling ECU of a battery cooling device according to a fifth embodiment of the present invention.
FIG. 13 is a second flowchart showing control in the battery cooling ECU of the battery cooling device.
FIG. 14 is a configuration diagram of a battery cooling device according to a sixth embodiment of the present invention.
FIG. 15 is a flowchart showing control in a battery cooling ECU of a battery cooling device according to a sixth embodiment of the present invention.
[Explanation of symbols]
1 Refrigeration cycle
11 Compressor
111 Electromagnetic clutch (switching means)
12 capacitors
13 Receiver
14a, 14b expansion valve
15a battery cooler
15b evaporator
100 Refrigerant piping
21 engine
22 Motor
23 Compressor motor
3a, 3b Solenoid valve (switching means)
4a Battery cooling ECU (control means)
4b Air conditioner ECU
4c Hybrid mechanism ECU (switching means)
51 Temperature sensor (battery temperature detection means)
52 Temperature sensor (air temperature detection means)
54 Throttle sensor (operating state detection means)
55 Engine speed sensor (operating state detection means)
56 Temperature sensor (refrigerant state detection means)
6 battery
7 Insulation case

Claims (4)

The battery is cooled by heat exchange between the compressor that changes the temperature of the refrigerant to high and high pressure, the condenser that liquefies the high-temperature and high-pressure refrigerant, the expansion valve that expands the liquefied refrigerant and lowers the refrigerant temperature, and the low-temperature refrigerant sent from the expansion valve and the battery. And a battery temperature detecting means for detecting the temperature of the battery, and supply of the low-temperature refrigerant to the battery cooler. Switching means for switching between and a stop thereof, and when the battery temperature detected by controlling the switching means falls below a preset lower limit value, the flow of the low-temperature refrigerant in the battery cooler is stopped, and the detected battery temperature is preset. A control means for circulating a low-temperature refrigerant to the battery cooler when exceeding the upper limit value ,
An evaporator for indoor air conditioning is connected to the refrigeration cycle in parallel with the battery cooler, and the switching means includes valve means for switching the flow path of the low-temperature refrigerant to either the battery cooler or the evaporator. ,
Air temperature detecting means for detecting the temperature of the air after heat exchange with the evaporator is provided, and the control means is used for controlling the low-temperature refrigerant until the detected air temperature is equal to or higher than a preset upper temperature during indoor air conditioning. The battery cooling device is set so as to be circulated through the battery cooler. 2. The battery cooling device according to claim 1, wherein the compressor is driven by engine power, and includes an operating state detecting means for detecting at least the engine speed as an operating state of the engine, and the control means. When the engine operating state is in a predetermined engine speed range set in advance and in a high-efficiency operating region that is a low-fuel-consumption region with good battery cooling fuel efficiency, Is a battery cooling device that is set so that a low-temperature refrigerant flows through the battery cooler even if the detected battery temperature does not exceed the upper limit temperature . 3. The battery cooling device according to claim 2, wherein the control means is set to switch the lower limit temperature to another set value on the low temperature side during flow control of the low temperature refrigerant to the battery cooler in the high efficiency operation region. Battery cooling device. 4. The battery cooling device according to claim 1 , further comprising refrigerant state detecting means for detecting a temperature or pressure of a refrigerant flowing through the battery cooler, wherein the control means has a temperature or pressure of the refrigerant in advance. A battery cooling device that is set to prohibit the flow of the low-temperature refrigerant to the battery cooler when it is equal to or lower than the set lower limit temperature or lower limit pressure .

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