• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A vehicle engine cooling device comprises: an engine cooling circuit (12) that circulates coolant to a motor (16) and a heat exchanger (20); at least one or more coolant circulation circuits (14) that circulate coolant to devices installed in the vehicle; a switching section which selectively switches between one or the other of a communication state for communicating the engine cooling circuit (12) and the coolant circulation circuit (14), and a cut-off state for isolating the engine cooling circuit (12) and the coolant circulation circuit (14); and a control section which, in a case in which an ignition switch is open, controls the switching section so that the communication state is established.
    公开号:FR3044709A1
    申请号:FR1661436
    申请日:2016-11-24
    公开日:2017-06-09
    发明作者:Yoichi Onishi;Nobuharu Kakehashi
    申请人:Toyota Motor Corp;
    IPC主号:
    专利说明:

    The present invention relates to an engine cooling device for a vehicle that circulates a liquid to an engine and cools the engine.
    Japanese Patent Application Laid-open (JP-A) No. 2000-257430 discloses a cooling device of an internal combustion engine which has a frost prevention mechanism which, before the temperature of the Outside air drops and the coolant freezes when a motor is stopped, recovers a portion of the coolant, which is in a frost prevention tube and a water jacket, into a tank. By providing a frost preventing mechanism in this manner, damage to the engine and the coolant circulation passage and the like due to volume expansion caused by freezing of the coolant can be prevented.
    However, in JP-A No. 2000-257430, in a case where there is provided a coolant circulation circuit which is provided so as to be isolated from an engine cooling circuit which includes the radiator and circulates the cooling water of the engine, there is room for improvement that a damage due to freezing of the circulating circuit of coolant that has been isolated can not be prevented.
    The present invention has been made in view of the circumstances described above, and provides an engine cooling device for a vehicle that prevents damage that is due to freezing in a case in which a coolant circulation circuit, which is connected to a motor cooling circulation circuit so as to be isolated, is provided.
    An engine cooling device for a vehicle of a first aspect of the present invention has: an engine cooling circuit which circulates coolant to a motor and a heat exchanger; a reservoir which is connected to the engine cooling circuit, and which stores the coolant to absorb pressure changes in the engine cooling circuit; at least one or more coolant circulation circuits that circulate the coolant to devices installed in the vehicle; a switching section which selectively switches between one or the other of a communication state for communicating the engine cooling circuit and the coolant circulation circuit, and a cut-off state for isolating the engine cooling system and the coolant circulation circuit; and a control section which, in a case in which an ignition switch is open, controls the switching section so that the communication state is established.
    In the first aspect, in the engine cooling circuit, the engine is cooled due to the coolant being circulated through the engine, and the heat of the coolant is dissipated due to the coolant which flows through the heat exchanger.
    The tank is connected to the engine cooling system, and the coolant is stored there. Pressure changes in the engine cooling circuit are absorbed by the reservoir.
    The switching section is switched selectively between one or the other of the communication state, wherein the switching section communicates the engine cooling circuit and the coolant circulation circuit, and the cut-off state, wherein the switching section isolates the engine cooling circuit and the coolant circulation circuit.
    In addition, at the control section, in a case in which the ignition switch is open, the switching section is controlled so that the engine cooling circuit and the coolant circulation circuit are placed in a state of communication. That is, in a case in which the ignition switch is open, the engine cooling circuit and the coolant circulation circuit are placed in a communication state, and therefore, even if a freeze occurs at the coolant circulation circuit, the pressure due to freezing can escape to the tank via the engine cooling circuit. Therefore, damage, which is due to freezing in a case in which there is a coolant circulation circuit which is connected to the engine cooling circuit so as to be isolated therefrom, can be prevented.
    It should be noted that, as a second aspect of the present invention, the control section can control the switching section so that the communication state is established, in at least one of a case in which the contactor ignition is initiated and a coolant temperature is detected to be less than a predetermined liquid temperature threshold value, and a case in which the ignition switch is open and an outside air temperature is detected to be less than a predetermined outside air temperature threshold value. That is, control by the control section can be achieved only in cases where there is the problem of the appearance of the coolant gel.
    In addition, as a third aspect of the present invention, the engine cooling device for a vehicle may further have a circulation section which circulates the coolant, and in a case in which the ignition switch is open, the control section can control the switching section so that the communication state is established, and can control the flow section so that the coolant is circulated until a temperature of the coolant becomes a predetermined stable state. Therefore, in the communication state, the fact that the engine cooling circuit portion freezes first, and then the coolant circulation circuit portion freezes and the pressure becomes unable to escape to the tank, can be prevented. It should be noted that, for example, a case in which it is detected that the temperature of the coolant has not changed for a predetermined time can be used as a predetermined stable state. Or, a case in which a predetermined time, beyond which the coolant temperature does not change even though the coolant is circulated through the flow section, flows can be used.
    In addition, as a fourth aspect of the present invention, in a case in which the ignition switch is closed, the control section may further control the switching section to maintain the communication state until no freezing of the coolant is detected. As a result, the fact that the coolant freezes and the circulation circuit is damaged when the ignition switch is closed and the state switches from the communication state to the cutoff state can be prevented. . It should be noted that in this case, as in the fifth aspect of the present invention, the absence of freezing of the coolant can be detected on the basis of an outside air temperature, a temperature of the liquid cooling, or a quantity driven at the moment of driving a circulation section which circulates the coolant. Here, the absence of freezing of the coolant means a state in which the coolant is not frozen, and also includes a state in which a portion of the coolant is frozen but the circulation of the coolant is possible . In addition, the amount entrained at the moment of driving the flow section, for example, the current value at the moment of rotation of a water pump which serves as a circulation section, can be used.
    In addition, as a fifth aspect of the present invention, the lack of freezing of the coolant can be detected based on an outside air temperature, a coolant temperature, or a a quantity that is driven during the driving of a circulation section that circulates the coolant.
    In addition, as a sixth aspect of the present invention, two of the coolant circulation circuits may be provided, and one of the coolant circulation circuits may have a battery temperature adjustment portion on a passage coolant circulation, and can be connected to the other of the coolant circulation circuits through a second switching section.
    In addition, as a seventh aspect of the present invention, one of the coolant circulation circuits may have a communication passage which is connected to a water pump and to the other of the liquid circulation circuits. cooling, and which adjusts a pressure, and the other of the coolant circulation circuits may have an exhaust gas recirculation cooling device.
    In addition, as an eighth aspect of the present invention, three of the coolant circulation circuits may be provided, and a first one of the coolant circulation circuits may have a vehicle transmission temperature adjustment portion. on a coolant circulation passage, and may be connected to a second one of the coolant circulation circuits via a second switching section, and a third of the coolant circulation circuits may have a second heat exchanger, which is provided on a coolant circulation passage on a windward side of the heat exchanger, and can be connected to the first of the coolant circulation circuits via a third switching section.
    Exemplary embodiments of the present invention will be described in detail on the basis of the following figures, in which:
    Fig. 1 is a schematic drawing showing the schematic structure of an engine cooling device for a vehicle relating to a first embodiment;
    Fig. 2 is a block diagram showing the structure of a control system of the engine cooling device for a vehicle related to the first embodiment;
    Fig. 3 is a flowchart showing some of the treatments that are performed at a control section of the engine cooling device for a vehicle related to the first embodiment;
    Fig. 4 is a flowchart showing some of the treatments that are performed at the control section of an engine cooling device for a vehicle related to a second embodiment;
    Fig. 5 is a schematic drawing showing the schematic structure of an engine cooling device for a vehicle relating to a third embodiment;
    Fig. 6 is a schematic drawing showing the schematic structure of a modified example of the engine cooling device for a vehicle relating to the third embodiment;
    Fig. 7 is a schematic drawing showing the schematic structure of an engine cooling device for a vehicle relating to a fourth embodiment;
    Fig. 8 is a drawing showing an exemplary operation during a cooling operation of the engine cooling device for a vehicle relating to the fourth embodiment;
    Fig. 9 is a drawing showing an example of operation during heating (during engine warm-up) of the engine cooling device for a vehicle related to the fourth embodiment; and
    Fig. 10 is a drawing showing an example of operation during heating (in a case in which the engine residual heat is sufficient after engine warm-up) of the engine cooling device for a vehicle relating to the fourth form of realization.
    Examples of the embodiments of the present invention are described in detail below with reference to the drawings. (First embodiment)
    Fig. 1 is a schematic drawing showing the schematic structure of an engine cooling device for a vehicle related to the present embodiment.
    An engine cooling device 10 for a vehicle related to the present embodiment has a plurality of circulation circuits for circulating cooling water which serves as a coolant. Concretely, the present embodiment describes an example in which, as shown in FIG. 1, the engine cooling device 10 for a vehicle has two circulation circuits which are a circulation circuit A 12 which serves as a control circuit. engine cooling, and a circulation circuit B 14 which serves as a coolant circulation circuit.
    The circulation circuit A 12 is a circulation passage at which the cooling water circulates through a motor 16 which serves as a power generating body, and the cooling water is circulated by means of a pump. engine water 18 which serves as a circulation section. The cooling water circulates in a water jacket inside the engine 16. In detail, a radiator 20, which serves as a heat exchanger which dissipates heat from the cooling water, is connected by the intermediate of a thermostat 19 to the circulation circuit A 12, and cooling water is circulated to the radiator 20 according to the opening / closing of the thermostat 19. That is to say that , below or at a predetermined temperature at which the cooling of the cooling water is necessary, the thermostat 19 is in a closed state, and a circulation of the cooling water to the radiator 20 is not realized , and the cooling water circulates in the motor 16 flowing through a bypass passage BP. In addition, in a case where the temperature of the cooling water exceeds the predetermined temperature, the thermostat 19 is opened, and cooling water is circulated to the radiator 20 and heat is dissipated. It should be noted that a mechanical water pump, which operates because of the driving of the motor 16, or an electric water pump which operates electrically, can be used as the engine water pump 18 of the circulation circuit A 12 In the present embodiment, the description is made using an example in which an electric water pump is used. In addition, for the thermostat 19 also, an electric thermostat can be used, or a mechanical thermostat can be used.
    A water temperature sensor 22 which detects the temperature of the cooling water is provided at the circulation circuit A 12. The water temperature sensor 22 is provided at, for example, the engine block, or the circulation passage which is connected to the engine block, or a thermostat housing in which the thermostat 19 is housed, or equivalent.
    A reservoir 24, which stores cooling water to absorb pressure changes due to the thermal expansion of the cooling water in the circulation circuits such as circulation circuit A 12 and the like, is connected to the radiator 20. On the other hand, the circulation circuit B 14 is a circulation passage in which cooling water circulates through various types of devices that are installed in the vehicle, and devices that can achieve a heat exchange with cooling water are provided at this level. As shown in FIG. 1, the present embodiment illustrates an example in which two devices which are a device A 26 and a device B 28 are provided at the level of the circulation circuit B 14. It should be noted that, by for example, a heater for heating the vehicle cab interior, an exhaust heat recovery device, an exhaust gas recirculation cooling device, a transmission or the like may be used as a device.
    In addition, the circulation circuit B 14 is connected via a two-way valve 30 to the circulation circuit A 12, and the circulation circuit A 12 and the circulation circuit B 14 can be switched selectively. to one of a communication state or a cutoff state.
    At the circulation circuit B 14 also, a water pump 32 which serves as a circulation section is provided, and the circulation of the cooling water in the circulation circuit B 14 is carried out because the water pump 32 is trained. In particular, in a case in which the circulation circuit A 12 and the circulation circuit B 14 are placed in the cut-off state by the two-way valve 30, a circulation of the cooling water in the circulation circuit B 14 is achieved by the water pump 32. In a case in which the two-way valve 30 is in the communication state, the cooling water can be circulated by the engine water pump 18, and this is enough not to drive the water pump 32.
    The structure of the control system of the engine cooling device 10 for a vehicle relating to the present embodiment is described next. Fig. 2 is a block diagram showing the structure of the control system of the engine cooling device 10 for a vehicle related to the present embodiment.
    The engine cooling device 10 for a vehicle related to the present embodiment has a control section 40 which provides control of the operations of the engine water pump 18 described above and the water pump 32 and equivalent, and the opening / closing of the two-way valve 30, and the like.
    The control section 40 is formed by a microcomputer which comprises, for example, a central processing unit, a read-only memory, a random access memory and the like.
    The water temperature sensor 22 described above, an outdoor air temperature sensor 36, the engine water pump 18, a two-way valve actuator 38 which serves as a switching section, and the water pump 32 are connected to the control section 40. It should be noted that the water temperature sensor 22 and the outdoor air temperature sensor 36 correspond to detection sections.
    The water temperature sensor 22 detects the temperature of the cooling water, and delivers the detection results to the control section 40. The outdoor air temperature sensor 36 detects the outside air temperature, and delivers the detection results at the control section 40. It should be noted that the present embodiment illustrates an example in which the outdoor air temperature sensor 36 is directly connected to the control section 40, but the detection results the outside air temperature can be acquired via another device such as an air conditioner or equivalent.
    As described above, the engine water pump 18 is provided at the engine 16, and, being driven, circulates the cooling water along the circulation passage.
    The two-way valve actuating device 38 is an actuating device for driving the opening and closing of the two-way valve 30. The switching of the circulation circuit A 12 and the circulation circuit B 14 between the state of communication and the state of interruption is realized because the two-way valve actuator 38 is driven.
    As described above, the cooling water of the circulation circuit B 14 is circulated because the water pump 32 is driven.
    On the basis of the detection results of the water temperature sensor 22, the control section 40 controls the two-way valve actuator 38, and performs a control to close the two-way valve 30 and set the circulation circuit A 12 and the circulation circuit B 14 in the cut-off state, in order to finish the temperature rise operation at an initial stage during the temperature rise operation. In addition, once the engine 16 has finished warming up and the temperature of the cooling water of the circulation circuit A 12 has risen sufficiently, the control section 40 makes a command to open the valve two-way 30 and put the circulation circuit A 12 and the circulation circuit B 14 in the communication state.
    Because the reservoir 24 is connected to the circulation circuit A 12 via the radiator 20, even if, once the vehicle stops and the ignition switch is open, the cooling water of the cooling circuit circulation A 12 freezes and expands, pressure escapes to the tank 24 via the radiator 20. However, in a case in which the circulation circuit B 14 is in the state of being isolated from the circuit A 12 by the two-way valve 30, if the cooling water in the circulation circuit B 14 freezes, there is the possibility that the pressure has no place to escape, and damage to product.
    Thus, in the present embodiment, in a case in which the vehicle is stopped and the ignition switch is open, in order to freeze the cooling water, the two-way valve 30 is open, and the circuit circulation A 12, to which the reservoir 24 is connected, and the circulation circuit B 14 are placed in the communication state, and the operation of the system is complete.
    In addition, when the circulation circuit A 12 and the circulation circuit B 14 have been placed in the communication state and the operation of the system is completed, and then operation of the system is started, the control section 40 controls the operation of the system. driving the two-way valve actuator 38 so as to maintain the communication state until the absence of freezing of the cooling water is detected. As a result, when the ignition switch is closed and the respective circulation circuits switch to the OFF state, the fact that the cooling water freezes and the circulation circuit B 14 is damaged can be prevented. It should be noted that, in the estimation that the cooling water is frozen or not, for example in a case in which the engine water pump 18 is caused to turn when the cooling water is frozen, the current value increases, and it can therefore be considered that the cooling water is frozen in a case in which the current value at the moment when the water pump 18 is rotated is greater than a current value predetermined. Or, whether the cooling water is frozen or not can be detected from the outside air temperature or the water temperature. In addition, instead of detecting the absence of freezing of the cooling water, the communication state can be maintained until the cooling water is circulated and the water temperature is stable. Here, the absence of freezing of the cooling water means a state in which the coolant is not frozen, and also includes a state in which a portion of the coolant is frozen and a circulation of the coolant is possible.
    Concrete processing which is carried out by the control section 40 of the engine cooling device 10 for a vehicle relating to the present embodiment is described next. Fig. 3 is a flowchart showing some of the treatments that are performed at the control section 40 of the engine cooling device 10 for a vehicle related to the present embodiment. It should be noted that the processes of FIG. 3 are excerpts from the characteristic parts among the processes that are performed by the control section 40. At the step 100, because the control section 40 acquires the detection results of the outdoor air temperature sensor 36 and water temperature sensor 22, the control section 40 acquires the outside air temperature and the water temperature, and the routine proceeds to step 102. In step 102, the control section 40 judges whether or not an unlit ignition switch has been opened. If this estimate is negative, the routine returns to step 100, and the processing described above is repeated. If this estimate is affirmative, the routine proceeds to step 104. In step 104, the control section 40 judges whether or not the outside air temperature is lower than a predetermined value. In this estimation, it is estimated whether an outside air temperature, which is lower than a predetermined outside air temperature threshold value for which there is a problem that the freezing of the circulation circuit A 12 and the circulation circuit B 14 occurs, was detected or not. If this estimate is negative, the routine proceeds to step 106, whereas if this estimate is affirmative, the routine proceeds to step 108. In step 106, the control section 40 estimates whether the water temperature is below a predetermined value or not. In this estimation, it is estimated whether a water temperature, which is less than a predetermined water temperature threshold value for which there is a problem that the freezing of the circulation circuit A 12 and the circulation circuit B 14 occurs, has been detected or not. If this estimate is affirmative, the routine proceeds to step 108, whereas if this estimate is negative, the routine proceeds to step 110.
    In step 108, by driving the two-way valve actuator 38, the control section 40 performs a control to open the two-way valve 30 and set the circulation circuit A 12 and the control circuit. B 14 circulation in the communication state, and the routine goes to step 110. Thus, the circulation circuit A 12 and the circulation circuit B 14 are placed in the communication state, and by therefore, even if the freezing of the cooling water occurs, the pressure at the time of expansion due to freezing can escape to the tank 24, and damage to the motor 16 and the circulation passages can be prevented. In step 110, the control section 40 performs a final processing or equivalent, and thus stops the system and completes the series of treatments.
    In this way, in the present embodiment, in a case in which the ignition switch is open, the circulation circuit A 12 and the circulation circuit B 14 are placed in the communication state. Therefore, even if the cooling water freezes, a pressure due to expansion due to freezing can escape to the tank 24, and damage to the devices can be prevented.
    It should be noted that at least one of step 104 and step 106 in the embodiment described above may be omitted. That is, the two-way valve 30 can be placed in the communication state independently of at least one of the outside air temperature and the water temperature in a case in which the contactor ignition is open. (Second embodiment)
    An engine cooling device for a vehicle relating to a second embodiment is described next. In the engine cooling device for a vehicle related to the second embodiment, only the processes that are performed at the control section 40 differ from the first embodiment, and therefore a description of the structure is omitted.
    In the second embodiment, once the ignition switch is open, the temperature of the cooling water in the circulation circuits is made uniform due to the fact that the water pumps (the engine water pump 18 and the water pump 32) are actuated. That is, when the circulation circuit A 12 freezes first and the circulation circuit B 14 then freezes, the pressure of the circulation circuit B 14 can not escape to the tank 24. Therefore, this is prevented by making the temperature of the cooling water uniform in the circulation circuits.
    Fig. 4 is a flowchart showing some of the treatments that are performed by the control section of the engine cooling device for a vehicle related to the present embodiment. It should be noted that the treatments of FIG. 4 are extracts from the characteristic parts among the treatments which are carried out by the control section 40. In addition, treatments which are identical to those of the first embodiment are described by being designated by the same numbers. In step 100, because the control section 40 acquires the detection results of the outdoor air temperature sensor 36 and the water temperature sensor 22, the control section 40 acquires the outside air temperature. and the water temperature, and the routine proceeds to step 102. In step 102, the control section 40 judges whether the unlit ignition switch has been opened. If this estimate is negative, the routine returns to step 100, and the processing described above is repeated. If this estimate is affirmative, the routine proceeds to step 104. In step 104, the control section 40 judges whether or not the outside air temperature is lower than a predetermined value. In this estimation, it is judged whether an outside air temperature, which is lower than a predetermined temperature at which there is a problem that the freezing of the circulation circuit A 12 and of the circulation circuit B 14 appears, has been detected or no. If this estimate is negative, the routine proceeds to step 106, whereas if this estimate is affirmative, the routine proceeds to step 108. In step 106, the control section estimates whether the temperature water is less or less than a predetermined value. In this estimation, it is judged whether a water temperature, which is lower than a predetermined temperature for which there is a problem that the freezing of the circulation circuit A 12 and the circulation circuit B 14 occurs, has been detected or no. If this estimate is affirmative, the routine proceeds to step 108, whereas if this estimate is negative, the routine proceeds to step 110. At step 108, driving the actuator two-way valve 38, the control section 40 performs a control so as to open the two-way valve 30 and place the circulation circuit A 12 and the circulation circuit B 14 in the communication state, and the sub- The program proceeds to step 120. As a result, the circulation circuit A 12 and the circulation circuit B 14 are placed in the communication state, and therefore, even if the cooling water gel occurs. the pressure at the time of expansion due to freezing can escape to the tank 24, and damage to the motor 16 and the circulation passages can be prevented. In step 120, the control section 40 operates the water pumps (the engine water pump 18 and the water pump 32), and the routine proceeds to step 122. It should be noted that, in step 120, the control section 40 is operable to actuate at least one of the engine water pump 18 and the water pump 32. In step 122, since the control 40 acquires the detection results of the water temperature sensor 22, the control section 40 acquires the water temperature, and the routine proceeds to step 124. In step 124, the control section 40 estimates whether the water temperature is stable or not. Specifically, by circulating the cooling water through the water pumps, the control section 40 estimates whether or not the water temperature is in a predetermined stable state in which the temperature of the water has not changed during a predetermined time. If this estimate is negative, the routine returns to step 120, and the processes described above are repeated. If the estimate is affirmative, the routine proceeds to step 110. In step 110, the control section 40 performs an end process that includes stopping the water pumps and the like, or the like, and thus stops the system and ends the series of treatments.
    In this way, in the present embodiment also, in a case in which the ignition switch is open, the circulation circuit A 12 and the circulation circuit B 14 are placed in the communication state. Therefore, even if the cooling water freezes, a pressure due to expansion due to freezing can escape to the tank 24, and damage to the devices can be prevented.
    In addition, in the present embodiment, the water pumps are further entrained, and the temperature of the cooling water is made uniform. Therefore, when the respective circulation circuits are in the communication state, it is possible to prevent the circulation circuit part A 12 from freezing first, and then the circulation circuit part B 14 from freezing and the pressure becomes unable to escape.
    It should be noted that at least one of step 104 and step 106 in the embodiment described above may be omitted. That is, in a case in which the ignition switch is open, the two-way valve 30 can be placed in the communication state and the water pumps can be operated independently of at least one of the outside air temperature and the water temperature.
    In addition, in the present embodiment, in step 124, the temperature of the water is detected and it is judged whether the water temperature is stable or not. The present invention is however not limited to this. For example, the water pumps can be driven for a predetermined time by determining, in advance and by experimentation or equivalent, the time until the water temperature is stable, and estimating whether this time is sufficient. has passed or not. (Third embodiment)
    An engine cooling device for a vehicle relating to a third embodiment is described next. Fig. 5 is a schematic drawing showing the schematic structure of an engine cooling device for a vehicle related to the present embodiment. It should be noted that structures which are identical to those of the first embodiment are designated by the same references, and a detailed description thereof is omitted.
    The respective embodiments described above describe examples in which two circulation circuits circulating the cooling water are provided. However, the present embodiment describes an example in which three circulation circuits are provided. That is, as shown in Fig. 5, a motor cooling device 11 for a vehicle related to the present embodiment has the circulation circuit A 12, the circulation circuit B 14 and the circulation circuit C 42, and the circulation circuit C 42 is added as a coolant circulation circuit to the embodiments described above.
    The circulation circuit A 12 is structured in the same manner as in the embodiments described above. At the circulation circuit B 14, an exhaust heat recovery device 27 is provided as device A 26 of the embodiments described above, and a heater 29 is provided as a device B 28.
    The circulation circuit C 42 is connected to the circulation circuit B 14 via a four-way valve 44 which serves as a switching section, and a battery 46 is provided in the circulation passage of the cooling water. . That is, at the circulation circuit C 42, a temperature adjustment of the battery 46 is possible using the heat of the cooling water. For example, when the temperature of the battery 46 is low, the battery 46 is not in an active state. Therefore, by putting the circulation circuit A 12, the circulation circuit B 14 and the circulation circuit C 42 in the communication states through the two-way valve 30 and the four-way valve 44, the temperature of the Battery 46 can be increased by using the heat of the cooling water. In addition, in a case in which the temperature of the battery 46 becomes a temperature of an active state, heating of the battery 46 more than necessary can be prevented by putting the circulation circuit B 14 and the circulation circuit C In a state in which the temperature of the battery 46 becomes excessively high, the battery 46 can also be cooled by dissipating heat towards the water of the reactor. cooling. It should be noted that the control section 40 controls the driving of the four-way valve 44 using a driver, in the same manner as the two-way valve 30 of the embodiments described above. Even in a case in which three circulation circuits are provided in this manner, in the same manner as in the respective embodiments described above, in a case in which the ignition switch is open, if the two-way valve 30 is placed in the communication state and the four-way valve 44 is also placed in the communication state, the pressure due to the expansion due to the gel escapes to the reservoir 24, and damage to the devices can be prevented. With regard to the actual processing of the control section 40, in step 108 of the respective embodiments described above, it is sufficient for the control section to control the actuating devices so that, at the moment when the two-way valve 30 is placed in the communication state, the four-way valve 44 is also placed in the communication state.
    In addition, when the circulation circuit A 12, the circulation circuit B 14 and the circulation circuit C 42 have been placed in the communication states and the operation of the system is completed, and then the operation of the system is started, the control section 40 may control to maintain the communication states of the respective circulation circuits until the absence of freezing of the cooling water is detected, as described above.
    It should be noted that in the third embodiment, as shown in FIG. 6, an exhaust gas recirculation cooling device 48 may be further provided at the circulation circuit B 14, and a water pump 50 which serves as a circulation section may further be provided at the circulation circuit C 42. In addition, in FIG. 6, depending on the addition of the water pump 50, a communication passage P is also added for a pressure adjustment of the circulation circuit C 42. By adding the water pump 50 in this way, also at the moment when the circulation circuit C 42 is isolated from the circulation circuit B 14, water The cooling circuit may be circulated to the battery 46, and the internal temperature of the battery 46 may be made uniform. In addition, in a case in which the water pump 50 is further provided and the cooling water is circulated when the ignition is stopped as in the second embodiment, the water pump 50 can be operated or no. (Fourth embodiment)
    An engine cooling device for a vehicle relating to a fourth embodiment is described next. Fig. 7 is a schematic drawing showing the schematic structure of an engine cooling device for a vehicle relating to the present embodiment. It should be noted that structures which are identical to those of the first embodiment are indicated by the same references, and a detailed description thereof is omitted.
    An engine cooling device 13 for a vehicle relating to a fourth embodiment is an example in which four circulation circuits through which the cooling water circulates are provided. As shown in FIG. 7, the circulation circuit A 12, the circulation circuit B 14, a circulation circuit C 52, and a circulation circuit D 54 are provided. That is, the circulation circuit C 52 and the circulation circuit D 54 are added to the first and second embodiments as coolant circulation circuits.
    The circulation circuit A 12 has the same structure as in the respective embodiments described above, and the circulation circuit B 14 has a structure similar to the modified example (Figure 6) of the third embodiment.
    The circulation circuit C 52 is connected to the circulation circuit B 14 via the four-way valve 44. A transmission 56, a water-cooled condenser 58, and the water pump 50 are provided at the level of the circuit C 52.
    The transmission 56 is the transmission of the vehicle, and a temperature adjustment thereof is made possible by the cooling water. In addition, the water-cooled condenser 58 is a heat exchanger that is included in a refrigerant cycle 60. The refrigerant cycle 60 comprises a compressor 62, a refrigeration device 64, a water-cooled condenser 58, and a refrigeration valve 60. 66. That is to say that, because of a refrigerant which is circulated while the refrigerant is compressed by the compressor 62 and the refrigerant is expanded by the expansion valve 66, the heat of the compressed refrigerant is dissipated at the water cooled condenser 58 and the cooling water is heated, and the cooling water is cooled due to the heat which is absorbed by the refrigerant expanded at the refrigerating device 64.
    The circulation circuit D 54 is connected to the circulation circuit C 52 via two three-way valves 68, 70. A second radiator 72, a cooling device 74, the refrigeration device 64 described above, and a water pump 76 which serves as a circulation section are provided at the circulation circuit D 54.
    In addition, at the circulation circuit D 54, a three-way valve 78 is further provided between the cooling device 74, the three-way valve 68 and the second radiator 72, and a three-way valve 80 is provided. between the refrigeration device 64, the three-way valve 70 and the second radiator 72.
    It should be noted that the respective valves (the four-way valve 44 and the three-way valves 68, 70, 78, 80) correspond to the switching sections, and, in the same manner as the two-way valve 30, are driven by actuators (not shown), and the operations of the actuators are controlled by the control section 40.
    In addition, Figure 7 is a drawing in which the radiator 20 and the second radiator 72 are provided on opposite sides. However, in reality, the second radiator 72 is provided on the windward side of the radiator 20, and the cooling wind passes through the second radiator 72 and the radiator 20 in that order.
    Examples of operation of the engine cooling device 13 for a vehicle relating to the fourth embodiment are described. Fig. 8 is a drawing showing an example of operation during the cooling operation of the engine cooling device 13 for a vehicle related to the present embodiment.
    At the time of the cooling operation, the control section 40 controls the actuating devices of the respective valves so that the respective valves are placed in the state shown in Fig. 8. That is, the two-way valve 30 is open, and cooling water passes through the two-way valve 30, and flows in parallel in the exhaust heat recovery device 27 and the heater 29, and is sucked by the engine water pump 18. In a case in which the thermostat 19 is open, the cooling water leaving the engine 16 also flows to the radiator 20. On the other hand, the water The coolant that exits the water-cooled condenser 58 passes through the four-way valve 44, the transmission 56, the three-way valve 68, the second radiator 72, and the three-way valve 70, and is circulated through the engine. way back to the condenser at r Thus, the heat that the cooling water receives at the water cooled condenser 58 and the transmission 56 is dissipated to the outside air at the second radiator 72. cooling that exits the refrigeration device 64 passes through the cooling device 74, the three-way valve 78 and the three-way valve 80, and is circulated back to the refrigeration device 64. Therefore , the air conditioning the vehicle cabin interior is cooled at the cooling device 74, and cold air is blown.
    Fig. 9 is a drawing showing an exemplary operation of the engine cooling device 13 for a vehicle related to the present embodiment during the heating operation (during engine warm-up).
    At the time of the heating operation during the engine temperature rise, the control section 40 controls the actuating devices of the respective valves so that the respective valves are placed in the states shown in Fig. 9. C ' that is, the two-way valve 30 is closed, and the cooling water exiting the engine 16 passes through the bypass passage BP and is sucked by the engine water pump 18. As a result, the cooling water of the circulation circuit A 12 is heated by the engine 16, and the temperature rise operation can be terminated at an early stage. On the other hand, the cooling water leaving the water-cooled condenser 58 passes through the four-way valve 44, the heater 29, the exhaust gas recirculation cooling device 48, the device exhaust heat recovery system 27, the four-way valve 44, the transmission 56, the three-way valve 68 and the three-way valve 70, and is circulated back to the water-cooled condenser. 58.
    In addition, the cooling water exiting the refrigerating device 64 passes through the cooling device 74, the three-way valve 78 and the second radiator 72, and is circulated back to the refrigeration device. 64. At this time, at the second radiator 72, the cooling water absorbs heat from the outside air.
    Fig. 10 is a drawing showing an exemplary operation of the engine cooling device 13 for a vehicle related to the present embodiment during the heating operation (a case in which the residual heat of the engine is sufficient after mounting in engine temperature).
    At the time of the heating operation in a case where the residual heat of the engine is sufficient after raising the temperature of the engine, the control section 40 controls the actuating devices of the respective valves so that the respective valves are placed in the states shown in Fig. 10. That is, the two-way valve 30 is open, and the cooling water passes through the two-way valve 30 and flows in parallel in the device exhaust heat recovery 27 and the heater 29, and is sucked by the engine water pump 18. On the other hand, the cooling water leaving the water-cooled condenser 58 passes through the four-way valve 44, the transmission 56, the three-way valve 68 and the three-way valve 70, and is circulated back to the water-cooled condenser 58. At this point, the cool water The cooling water exiting the refrigerating device 64 passes through the cooling device 74, the three-way valve 78, the second radiator 72 and the three-way valve 80. and is circulated back to the refrigeration device 64. At this time, at the second radiator 72, the cooling water absorbs heat from the outside air.
    In this structure also, in the same way as in the respective embodiments described above, in a case in which the ignition switch is open, if the control section 40 controls the actuating devices of the respective valves of such that the respective circulation circuits communicate, the pressure due to expansion due to the gel escapes to the reservoir 24, and damage to the devices can be prevented. Specifically, as shown in FIG. 7, the two-way valve 30 is open, and the four-way valve 44 is placed in a communication state of the circulation circuit B 14 and the circulation circuit C 52. , the three-way valve 68 is placed in a communication state of the circulation circuit D 54 with the circulation circuit B 14 via the circulation circuit C 52, and the three-way valve 70 is placed in a state communicating the flow passage, which is between the three-way valve 68 and the three-way valve 70, with the water-cooled condenser 58. In addition, the three-way valve 78 is placed in a state of flow. communication of the flow passage, which comprises the cooling device 74, with the circulation circuit C 52, and the three-way valve 80 is placed in a communication state of the flow passage, which is between the three-way valve lanes 78 and the va Three-way valve 80, to the refrigerating device side 64. That is, the control section 40 controls the actuating devices of the respective valves so that all the flow passages are in 24. Thus, even if the cooling water freezes, a pressure due to expansion due to freezing can escape to the tank 24, and damage to the devices can be prevented.
    In addition, in a case in which the ignition switch is open, the respective circulation circuits may be in communication, and the cooling water may be circulated as in the second embodiment. In this case, the water pumps can all be driven, but it is possible to drive only the engine water pump 18, or to drive other water pumps.
    Moreover, in the present embodiment also, when the respective circulation circuits have been placed in the communication states and operation of the system is completed, and then, operation of the system is started, the control section 40 can perform control so as to maintain the communication states of the respective circulation circuits until the absence of freezing of the cooling water is detected.
    It should be noted that the fourth embodiment describes an example in which three circulating liquid circuits are provided as coolant circulation circuits. However, even if four or more coolant circuits are provided, effects that are similar to those of the respective embodiments described above are achieved if all the circulating liquid circuits are placed in communication states in a case in which the ignition switch is open.
    In addition, the processes that are performed at the control section 40 in the embodiments described above may be made to be software processes that are performed by running a program, or may be processes that are made by material. Or the treatments can be brought to be treatments that combine the software and the hardware. In addition, the program that is stored in the ROM can be stored on different types of storage media and distributed.
    Moreover, the present invention is not limited to the above, and, in addition to the above, can naturally be implemented by being modified in different forms in a range that does not deviate from the essential of it.
    权利要求:
    Claims (8)
    [1" id="c-fr-0001]
    An engine cooling device for a vehicle, characterized in that it comprises: an engine cooling circuit (12) configured to circulate a coolant to a motor (16) and a heat exchanger (20) ; a reservoir (24) which is connected to the engine cooling circuit (12) and which is configured to store the coolant to absorb pressure changes in the engine cooling circuit (12); at least one or more coolant circulation circuits (14, 42, 52, 54) configured to circulate coolant to devices installed in the vehicle; a switching section (38, 44) configured to selectively switch between one or the other of a communication state to communicate the engine cooling circuit (12) and the coolant circulation circuit (14, 42, 52, 54), and a cut-off state for isolating the engine cooling circuit (12) and the coolant circulation circuit (14, 42, 52, 54); and a control section (40) which, in a case in which an ignition switch is open, is configured to control the switching section (38, 44) so that the communication state is established.
    [2" id="c-fr-0002]
    The engine cooling device for a vehicle according to claim 1, wherein the control section (40) is configured to control the switching section (38,44) so that the communication state is established in at least one of a case in which the ignition switch is open and a coolant temperature is detected to be less than a predetermined liquid temperature threshold value, and a case in which the ignition switch is ignition is open and an outdoor air temperature is detected to be less than a predetermined outside air temperature threshold value.
    [3" id="c-fr-0003]
    An engine cooling device for a vehicle according to claim 1 or claim 2, further comprising: a circulation section (18, 32, 50, 76) configured to circulate the coolant, wherein, in a in which case the ignition switch is open, the control section (40) is configured to control the switching section (38, 44) so that the communication state is established, and to control the circulation section (18, 32, 50, 76) such that the coolant is circulated until a temperature of the coolant becomes a predetermined stable state.
    [4" id="c-fr-0004]
    An engine cooling device for a vehicle according to any one of claims 1 to 3, wherein, in a case in which the ignition switch is closed, the control section is configured to (40) control in addition to the switching section (38, 44) for maintaining the communication state until the absence of freezing of the coolant is detected.
    [5" id="c-fr-0005]
    An engine cooling device for a vehicle according to claim 4, wherein the absence of freezing of the coolant is detected on the basis of an outside air temperature, a coolant temperature, or a quantity driven at the moment of driving a circulation section (18, 32, 50, 76) which circulates the cooling liquid.
    [6" id="c-fr-0006]
    The engine cooling device for a vehicle according to claim 1, wherein two of the coolant circulation circuits (14, 42) are provided, and one of the coolant circulation circuits (14, 42) has a battery temperature adjusting portion on a coolant circulation passage, and is connected to the other of the coolant circulation circuits (14, 42) through a second switching section (44).
    [7" id="c-fr-0007]
    The engine cooling device for a vehicle according to claim 6, wherein said one of the coolant circulation circuits has a communication passage which is connected to a water pump and to the other of the circulating circulation circuits. coolant, and which is configured to adjust a pressure, and the other one of the coolant circulation circuits has an exhaust gas recirculation cooling device (48).
    [8" id="c-fr-0008]
    The engine cooling device for a vehicle according to claim 1, wherein three of the coolant circulation circuits (14, 52, 54) are provided, and a first one of the coolant circulation circuits has a portion for adjusting the transmission temperature of the vehicle on a coolant circulation passage, and is connected to a second of the coolant circulation circuits via a second switching section, and a third of the circuits coolant circulation circuit has a second heat exchanger (72), which is provided on a coolant circulation passage on a windward side of the heat exchanger, and is connected to the first of the circulation circuits of the coolant through a third switching section.
    类似技术:
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    同族专利:
    公开号 | 公开日
    US20170159545A1|2017-06-08|
    FR3044709B1|2020-07-10|
    CN106837505B|2019-05-03|
    CN106837505A|2017-06-13|
    DE102016123023A1|2017-06-08|
    JP2017106329A|2017-06-15|
    US10125662B2|2018-11-13|
    JP6358243B2|2018-07-18|
    DE102016123023B4|2019-10-10|
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    法律状态:
    2017-10-12| PLFP| Fee payment|Year of fee payment: 2 |
    2018-10-11| PLFP| Fee payment|Year of fee payment: 3 |
    2019-02-01| PLSC| Publication of the preliminary search report|Effective date: 20190201 |
    2019-10-15| PLFP| Fee payment|Year of fee payment: 4 |
    2020-10-13| PLFP| Fee payment|Year of fee payment: 5 |
    2021-11-09| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    JP2015-238527|2015-12-07|
    JP2015238527A|JP6358243B2|2015-12-07|2015-12-07|Engine cooling device for vehicle|
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