JP2017160831A - Drive control device for electric oil pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a drive control device for an electric oil pump 46, the drive control device being configured in such a way that the generation, in an oil pan 44, of ice having a level causing clogging of a lubricating oil flow passage can be suppressed.SOLUTION: An internal combustion engine 40 comprises an oil pan 44 for accommodating lubricating oil for use in lubrication of an internal combustion engine body 42 having a cylinder block and a cylinder head, and of each part of the internal combustion engine body 42. A strainer 48 having a mesh structure at a suction port 50 is accommodated in the oil pan 44, and an electric oil pump 46 is arranged at a position downstream of the strainer 48. The electric oil pump 46 sucks the lubricating oil in the oil pan 44, and discharges it to the engine body 42 side. When a stop time of the electric oil pump 46 becomes long after it is determined that a moisture content in the lubricating oil is high, a control device 60 drives the electric oil pump 46 for a prescribed time to agitate the lubricating oil.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a drive control device for an electric oil pump that drives an electric oil pump for sucking lubricating oil in an oil pan and using it for lubricating an internal combustion engine.

  For example, Patent Document 1 discloses that a suction port is immersed in lubricating oil in an oil pan of an internal combustion engine, extends downstream of the suction port, and extends downstream of the bent portion in the flow channel having the bent portion. A strainer having a filter covering the entire cross-section orthogonal to is described. This strainer is provided with a collection net between the filter and the suction port, which divides the cross section of the flow path in the bent portion, which is perpendicular to the extending direction, into the inside and the outside of the bent portion. This is because the water contained in the lubricating oil becomes ice while the internal combustion engine is stopped in cold regions, etc., and the filter is clogged by sucking the ice together with the lubricating oil from the suction port by the oil pump when the internal combustion engine is started. It aims to suppress this. That is, since the ice sucked from the suction port is captured by the outer portion of the bent portion in the flow path separated by the collection net by centrifugal force, clogging of the filter can be suppressed.

JP, 2015-161230, A

  In the case of the above technology, as a countermeasure against clogging caused by ice, it is necessary to configure a strainer so that the lubricating oil in the oil pan can be used for lubricating the internal combustion engine. Cannot be prevented from occurring in the oil pan.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide an electric oil pump capable of suppressing the occurrence of ice at a level that causes clogging in the flow path of the lubricating oil in the oil pan. To provide a drive control device.

Hereinafter, means for solving the above-described problems and the effects thereof will be described.
1. In a drive control device for an electric oil pump for driving an electric oil pump for sucking the lubricating oil from a suction port immersed in the lubricating oil in an oil pan and using it for lubricating the internal combustion engine, the internal combustion engine is stopped. A stirring processing unit that drives the electric oil pump to stir the lubricating oil in the oil pan, a water content acquisition processing unit that acquires a water content in the lubricating oil, and the lubricating oil A timing processing unit that counts a stop period that is not used for lubrication of the internal combustion engine and is not stirred by the stirring processing unit, and the stirring processing unit includes the moisture content acquisition processing unit When the amount of water acquired by the above is equal to or greater than a predetermined amount, the stirring process is performed on condition that the stop period timed by the timekeeping processing unit reaches a threshold value.

  The lubricating oil contains water mainly because the water produced by the combination of hydrogen in the fuel with oxygen when the fuel burns in the combustion chamber before warming up the internal combustion engine is still water. It is caused by mixing in lubricating oil that has not reached its boiling point. When water is mixed into the lubricating oil, it is in an emulsion state in which the lubricating oil and water are mixed. However, a mixed liquid of lubricating oil and water in an emulsion state takes time if left in a stationary state if the amount of water in the mixed liquid exceeds the capacity of the surfactant in the lubricating oil. As a result, it separates into lubricating oil and water. And the water isolate | separated from lubricating oil solidifies at low temperature and becomes ice.

  Here, when the amount of moisture in the lubricating oil is large, there is a possibility that the separation of water from the lubricating oil becomes significant due to the longer stop period. In other words, there is a possibility that an amount of water that can become ice at a level that interferes with the lubrication process due to clogging in the flow path of the lubricating oil may be separated. Therefore, in the above configuration, when the moisture amount acquired by the moisture amount acquisition processing unit is equal to or greater than the specified amount, the stirring processing unit performs the stirring process on the condition that the stop period timed by the timing processing unit reaches a threshold value. Therefore, even if a small amount of water has already been separated, the water can be mixed with the lubricating oil and returned to the emulsion state. For this reason, in the said structure, since it can suppress that the isolation | separation of the water from lubricating oil becomes remarkable, it can suppress that the level of ice which clogs the distribution path of lubricating oil arises in an oil pan.

  2. The drive control device for the electric oil pump according to claim 1, further comprising a specified amount determination processing unit that determines whether or not a moisture amount estimated by the moisture amount acquisition processing unit is equal to or greater than the specified amount, and the stirring processing unit Does not execute the stirring process when it is determined by the specified amount determination processing unit that the amount is less than the specified amount.

  In the above configuration, since the agitation processing unit does not execute the agitation process when the specified amount determination processing unit determines that the water content is less than the specified amount, the agitation process is performed when the amount of water separated from the lubricating oil can be ignored. Can be prevented from being executed in vain. Therefore, waste of energy can be suppressed.

  3. In the drive control device for the electric oil pump according to 1 above, a period determination processing unit that determines whether or not the stop period timed by the time measurement processing unit has reached a determination value, and the amount of water is not less than the specified amount In this case, the determination value is set to the same value as the threshold value, and when the water content is less than the specified amount, a determination value variable setting processing unit that sets the determination value to an execution suppression value larger than the threshold value; The stirring processing unit executes the stirring processing on the condition that the stop period has reached the determination value by the period determination processing unit, and the threshold value is the electric oil A value is set to suppress the possibility of clogging due to ice in the flow path of the lubricating oil sucked from the oil pan by the pump, and the execution suppression value is set by the electric oil pump. Wherein are set to helpless value in order to suppress the risk of clogging is caused by the ice flow path of the lubricating oil sucked from the oil pan.

  When the amount of moisture in the lubricating oil is small, it may be a waste of energy to perform the stirring process. Here, the execution suppression value is set to a powerless value for suppressing the possibility of clogging caused by ice. This means that the execution suppression value is a value that is not constrained by the purpose of suppressing the formation of ice in the oil pan, so that the stirring process is performed particularly when the amount of water is less than the specified amount. It can be set to a value that suppresses this.

  When the moisture amount is a specified amount, “the stirring process is performed on the condition that the period determination processing unit determines that the stop period has reached the determination value” means that “the stop period reaches a threshold value. This means that the stirring process is executed on the condition.

  4). In the drive control device for the electric oil pump according to 2 or 3, when the water content acquired by the water content acquisition processing unit is greater than or equal to the specified amount, the threshold value is higher than when the water content is high. Is provided with a threshold variable setting processing unit for setting the value to a small value.

  When the amount of water in the lubricating oil is large, the time from when the lubricating oil and water are in an emulsion state until the separation of water becomes significant is shorter than when the amount of water is small. For this reason, when the threshold value is set to a fixed value capable of suppressing the separation of water from the lubricating oil, there is a concern that the stirring process may be performed earlier than necessary when the amount of water is small. The In this regard, in the above configuration, the threshold value is variably set according to the amount of water, so that the execution of the stirring process can be delayed as much as possible while suppressing the separation of water from the lubricating oil.

  5. In the drive control device for the electric oil pump according to 2 or 3, the deterioration degree is calculated based on a deterioration information acquisition processing unit that acquires deterioration information of the lubricating oil and information acquired by the deterioration information acquisition processing unit. A threshold variable setting processing unit that sets the threshold value to a smaller value when larger than when smaller.

  When the degree of deterioration of the lubricating oil is large, the time from the emulsion state of the lubricating oil and water until the separation of water becomes significant is shorter than when the degree of deterioration of the lubricating oil is small. For this reason, when the threshold value is set to a fixed value capable of suppressing the separation of water from the lubricating oil, there is a concern that the stirring process may be performed earlier than necessary when the degree of deterioration is small. The In this regard, in the above configuration, the threshold value is variably set according to the degree of deterioration, so that the execution of the stirring process can be delayed as much as possible while suppressing the separation of water from the lubricating oil.

  6). In the drive control device for the electric oil pump according to 2 or 3, the temperature acquisition processing unit that acquires the temperature, and the threshold value is set to a smaller value than when the temperature acquired by the temperature acquisition processing unit is low. A threshold variable setting processing unit to be set.

  When the temperature of the lubricating oil is low, the time from the emulsion state of the lubricating oil and water until the separation of water becomes significant is shorter than when the temperature is high. For this reason, when the threshold value is set to a fixed value capable of suppressing the separation of water from the lubricating oil, the stirring process is performed earlier than necessary when the temperature of the lubricating oil is high. There is concern. In this regard, in the above configuration, the stirring process is performed while suppressing the separation of water from the lubricating oil by suppressing the separation of the water from the lubricating oil by variably setting the threshold according to the temperature having a correlation with the temperature of the lubricating oil during the stop period. Execution can be delayed as much as possible.

  7). The drive control apparatus for an electric oil pump according to any one of 1 to 6 above, wherein the stirring process is performed by using a fluid sucked from a discharge side when lubricating the internal combustion engine in the electric oil pump. In the pump, the oil pan is discharged from the suction side when the internal combustion engine is lubricated.

  In the above configuration, in the agitation process, the fluid sucked from the discharge side during the lubrication process is discharged to the suction side during the lubrication process by the electric oil pump. Here, when the stop period reaches the threshold value, when the lubricating oil in the lubrication path flows out to the outside and the lubricating oil and air are mixed in the lubrication path, the electric oil pump is At least air is sucked and the sucked air is discharged to the oil pan. Thereby, the lubricating oil and water in the oil pan are agitated. On the other hand, if the lubrication path is filled with lubricating oil even when the stop period reaches the threshold, at least at the beginning of the agitation process, the lubricating oil sucked and sucked by the electric oil pump Will be discharged into the oil pan. Thereby, the lubricating oil and water in the oil pan are agitated.

The figure which shows the drive system of the vehicle concerning 1st Embodiment. The flowchart which shows the procedure of the process which estimates the moisture content in the lubricating oil concerning the embodiment. 6 is a flowchart showing a procedure of timer setting processing according to the embodiment; The flowchart which shows the procedure of the process which determines the stirring process and its execution concerning the embodiment. The flowchart which shows the procedure of the calculation process of the deterioration parameter of the lubricating oil concerning 2nd Embodiment. The flowchart which shows the procedure of the estimation process of the average temperature concerning the embodiment. 6 is a flowchart showing a procedure of timer setting processing according to the embodiment; 10 is a flowchart showing a procedure of timer setting processing according to the third embodiment. The flowchart which shows the procedure of the setting process of the timer concerning 4th Embodiment. The flowchart which shows the procedure of the process which determines the stirring process concerning 5th Embodiment, and its execution.

<First Embodiment>
Hereinafter, a first embodiment of a drive control device for an electric oil pump will be described with reference to the drawings.

  FIG. 1 shows a vehicle drive system according to this embodiment. The drive system shown in FIG. 1 constitutes a series / parallel hybrid system. As shown in FIG. 1, the internal combustion engine 40 is mechanically connected to the carrier C of the planetary gear mechanism (power split mechanism 10), and the motor generator 14 is mechanically connected to the sun gear S of the power split mechanism 10. The motor generator 12 is mechanically coupled to the ring gear R of the power split mechanism 10. Here, among the three rotating bodies constituting the power split mechanism 10, the sun gear S, the carrier C, and the ring gear R, in which the object is mechanically connected, means that the object first transmits power. It is a possible rotating body. Further, the drive wheel 16 is mechanically coupled to the ring gear R.

  The motor generator 12 is connected to an assembled battery 26 that is a series connection body of battery cells via an inverter 18, a DCDC converter 22, and a system main relay (SMR 24). The motor generator 14 is connected to the assembled battery 26 via the inverter 20, the DCDC converter 22 and the SMR 24. Between the SMR 24 and the assembled battery 26, a charger 28 for charging the assembled battery 26 with electric power from a commercial power source 30 outside the vehicle is connected.

  The internal combustion engine 40 includes an engine main body 42 having a cylinder block and a cylinder head, and an oil pan 44 that stores lubricating oil used for lubricating each part of the engine main body 42. A strainer 48 is accommodated in the oil pan 44, and an electric oil pump 46 is provided downstream of the strainer 48. The electric oil pump 46 sucks the lubricating oil in the oil pan 44 and discharges it to the engine body 42 side. The electric oil pump 46 includes an electric motor 46a. When the electric motor 46a rotates, the electric oil pump 46 can discharge lubricating oil to the engine main body 42 while keeping the crankshaft of the internal combustion engine 40 stationary.

  The strainer 48 is arranged such that the suction port 50 faces the bottom surface of the oil pan 44. This is a setting for allowing the suction port 50 to be constantly immersed in the lubricating oil. The suction port 50 has a mesh structure for preventing a certain amount of impurities contained in the lubricating oil in the oil pan 44 from flowing into the electric oil pump 46 through the suction port 50. The mesh structure is configured by, for example, forming a plurality of holes of several millimeters, and prevents a larger one from flowing into the electric oil pump 46 from the suction port 50.

  The control device 60 includes a microcomputer (microcomputer 61) having a central processing unit (CPU 62) and a memory 64, and a timer 66. The timer 66 activates the microcomputer 61 when the timer 61 can perform the timing operation even when the power of the microcomputer 61 is turned off and the timed period reaches a preset time. It is hardware with functions.

  The control device 60 executes various controls by causing the CPU 62 to execute the program stored in the memory 64. In particular, the control device 60 controls the internal combustion engine 40 as a control target and the control amount (torque, exhaust component). The control device 60 includes a rotation speed sensor 70 for detecting the rotation speed NE of the internal combustion engine 40, a water temperature sensor 72 for detecting the cooling water temperature THW of the internal combustion engine 40, an outside air temperature sensor 74 for detecting the outside air temperature THO, and the rotation speed of the electric motor 46a. The output value of the motor rotation sensor 76 that detects Nm is captured. Further, the control device 60 drives the electric oil pump 46 while the internal combustion engine 40 is being driven, and lubricates the lubricating oil in the oil pan 44 to each location of the engine body 42.

  The HV control device 80 controls the inverters 18 and 20, the DCDC converter 22, the charger 28, and the like. The HV control device 80 is activated on condition that the power switch 82 is turned on, and closes the SMR 24 so that the vehicle can run. The HV control device 80 activates the control device 60 when a request to drive the internal combustion engine 40 occurs. Incidentally, starting the control device 60 means starting the microcomputer 61.

  The control device 60, the HV control device 80, the electric motor 46a and the like are driven by electric power from the auxiliary battery 84. The auxiliary battery 84 has a terminal voltage of 12 V, for example, and has a smaller fully charged charge than the assembled battery 26. Incidentally, the startup process of the microcomputer 61 by the timer 66 can be realized, for example, by providing a relay between the auxiliary battery 84 and the microcomputer 61 and the timer 66 having a function of operating the relay.

  The HV control device 80 causes the vehicle to travel using the power of the assembled battery 26 charged by the charger 28 as much as possible. Therefore, when the charging rate of the assembled battery 26 exceeds the specified value and sufficient power can be applied to the drive wheels 16 by the power generated by the motor generator 12, the internal combustion engine 40 and the motor generator 14 are stopped. On the other hand, in addition to the motor generator 12, the motor generator 14 is driven when the vehicle is required to travel even though the charging rate of the assembled battery 26 is equal to or less than the specified value. Then, the internal combustion engine 40 is driven via the control device 60.

  Thus, in this embodiment, since the electric power of the assembled battery 26 is used as much as possible as energy for running the vehicle, the drive duration time of the internal combustion engine 40 tends to be shortened. For this reason, a situation in which the temperature of the lubricating oil does not become 100 ° C. or more during the driving of the internal combustion engine 40 is likely to occur. Here, during the driving of the internal combustion engine 40, water generated by the combustion of the fuel is mixed into the lubricating oil. The water mixed in the lubricating oil is vaporized and removed from the lubricating oil when the temperature of the lubricating oil is 100 ° C. or higher. On the other hand, when the temperature of the lubricating oil does not rise sufficiently, the lubricating oil contains water even after the internal combustion engine 40 is stopped, resulting in an emulsion state in which the lubricating oil and water are mixed. When the amount of water in the mixture exceeds the ability of the surfactant in the lubricant, the mixed liquid of the lubricating oil and water in the emulsion state is maintained by stopping the internal combustion engine 40. Separate into lubricating oil and water. The separated water remains at the bottom of the oil pan 44 because the density of the water is higher than the density of the lubricating oil. When the condensed water is cooled below the freezing point, ice is generated in the lubricating oil.

  Here, when the amount of water separated from the lubricating oil is large (for example, about 10 percent), the entire surface of the suction port 50 may be covered with ice. On the other hand, even if the amount of water separated from the lubricating oil is not so large as to cover the entire surface of the suction port 50, the mesh structure of the suction port 50 is reduced by small ice particles by driving the electric oil pump 46. There is a risk of clogging. If clogging occurs, the lubricating oil of the internal combustion engine 40 may be hindered, such as the lubricating oil cannot be sufficiently supplied to the engine main body 42 by the electric oil pump 46 and the sliding portion of the internal combustion engine 40 may be seized. .

Therefore, in the present embodiment, when water is contained in the lubricating oil, the following processing is executed so as to suppress separation of water from the lubricating oil.
FIG. 2 shows a procedure for estimating the amount of water DW in the lubricating oil. The processing shown in FIG. 2 is realized by the CPU 62 executing the program stored in the memory 64. Note that the processing shown in FIG. 2 is repeatedly executed at a predetermined cycle, for example.

  In the series of processes shown in FIG. 2, the CPU 62 first determines whether or not the internal combustion engine 40 is being driven (S10). This process is for determining whether or not to execute the process for calculating the moisture amount DW. If the CPU 62 determines that it is being driven (S10: YES), it acquires the injection amount Q of the internal combustion engine 40 (S12), acquires the cooling water temperature THW (S14), and sets the outside temperature THO. Obtained (S16), the rotational speed NE is obtained (S18). Then, the CPU 62 estimates the temperature of the lubricating oil (oil temperature Toil) based on the rotational speed NE and the coolant temperature THW (S20). Here, when the rotational speed NE is high, the oil temperature Toil is estimated to be higher than when the rotational speed NE is low. This is because the rise in the oil temperature Toil is mainly due to the heat generated in the sliding portion of the engine body 42, and the amount of generated heat increases as the rotational speed NE increases. Further, when the coolant temperature THW is high, the oil temperature Toil is estimated to be higher than when the coolant temperature THW is low. This is because the amount of heat received by the lubricating oil from the engine body 42 increases as the temperature of the engine body 42 increases.

  Then, the CPU 62 determines whether or not the oil temperature Toil is equal to or higher than the threshold temperature Toilth (S22). This process is a process for determining whether or not water is contained in the lubricating oil. The threshold temperature Toilth is set to about the boiling point of water (100 ° C.). When determining that the temperature is equal to or higher than the threshold temperature Toilth (S22: YES), the CPU 62 sets the water content DW to zero (S24). On the other hand, when determining that the temperature is lower than the threshold temperature Toilth (S22: NO), the CPU 62 updates the moisture amount DW to the increasing side by adding the moisture update amount ΔDW to the current moisture amount DW (weight: mg). (S26). Here, the water renewal amount ΔDW is set to a larger value when the cooling water temperature THW is low than when it is high. This is because when the cooling water temperature THW is low, the water generated by the combination of hydrogen and oxygen in the fuel due to the combustion of the fuel is liable to liquefy, and the liquefied water is discharged out of the vehicle together with the exhaust. It is because it is hard to be done. Further, when the injection amount Q is large, the water renewal amount ΔDW is set to a larger value than when the injection amount Q is small. This is because the greater the amount of fuel, the more water molecules that are oxidized and produced. When the injection amount Q is zero, the moisture update amount ΔDW may be set to zero. Further, the moisture renewal amount ΔDW is set to a larger value when the outside air temperature THO is low than when the outside air temperature THO is high. This is because when the outside air temperature THO is low, the water generated by the combination of hydrogen and oxygen in the fuel due to the combustion of the fuel is liquefied more easily than when the outside air temperature THO is high.

  Specifically, in the present embodiment, a three-dimensional map that defines the relationship between the coolant temperature THW, the injection amount Q, the outside air temperature THO, and the moisture update amount ΔDW is stored in the memory 64 in advance, and this three-dimensional map is stored. Utilizing this, the water renewal amount ΔDW is calculated. The map includes each of a plurality of discrete values of input variables (here, cooling water temperature THW, injection amount Q, and outside air temperature THO), and a value of an output variable (here, moisture update amount ΔDW). It is the data which shows the set of. When the actual input variable does not correspond to any of the input variable values set in the map, the CPU 62 calculates the output variable by interpolation calculation.

Note that the CPU 62 once ends the series of processes shown in FIG. 2 when the processes of steps S24 and S26 are completed or when a negative determination is made in step S10.
FIG. 3 shows the procedure of the timer 66 setting process. The processing shown in FIG. 3 is realized by the CPU 62 executing the program stored in the memory 64. Note that the process shown in FIG. 3 is repeatedly executed at a predetermined cycle, for example.

  In the series of processes shown in FIG. 3, the CPU 62 first determines whether or not the electric oil pump 46 is being driven (S30). When determining that the electric oil pump 46 is not being driven (S30: NO), the CPU 62 determines whether or not the electric oil pump 46 has been switched from the drive state to the stop state (S32). This process is a determination process of whether or not an affirmative determination is made in step S30 in the previous control cycle of the process shown in FIG. 3 and a negative determination is made in the current control cycle. When determining that it is the time of switching (S32: YES), the CPU 62 acquires the moisture amount DW calculated by the process of FIG. 2 (S34). Next, the CPU 62 determines whether or not the moisture amount DW is equal to or greater than the specified amount DWth (S36). This process is for determining whether or not the execution condition of the timing process of the stop period of the electric oil pump 46 by the timer 66 is satisfied. Here, the prescribed amount DWth is set to a lower limit value of an amount that may cause clogging in the suction port 50 when water is separated from the lubricating oil and becomes ice. If the CPU 62 determines that the amount is greater than or equal to the specified amount DWth (S36: YES), the timer 66 is set so as to notify the CPU 62 when the timing period reaches the threshold value Tth by starting the timing operation (S38). . Here, the threshold value Tth is shorter than a period until the water is separated from the lubricating oil by an amount that may cause clogging in the suction port 50 when the water separated from the lubricating oil becomes ice (for example, 15 Day). In setting the threshold value Tth, it is assumed that the water contained in the lubricating oil is not less than the specified amount DWth and not more than the assumed maximum amount. Here, the assumed maximum amount is, for example, the maximum amount of water that is assumed to be generated when the vehicle is used only in the coldest region where the vehicle is assumed and the internal combustion engine 40 is driven in various ways.

  On the other hand, when determining that the electric oil pump 46 is being driven (S30: YES), the CPU 62 resets the timer 66 (S40). In other words, the CPU 62 executes a process for stopping the timing operation of the timer 66 and a process for erasing the memory between the timings until then. Note that when the processes of steps S38 and S40 are completed or when a negative determination is made in steps S32 and S36, the CPU 62 once ends the series of processes shown in FIG.

  FIG. 4 shows a process when the microcomputer 61 is activated. The processing shown in FIG. 4 is realized by the CPU 62 executing a program stored in the memory 64. This process is executed with the start of the microcomputer 61 as a trigger.

  In the series of processing shown in FIG. 4, the CPU 62 first determines whether or not the timer 66 has been notified (S50). That is, the microcomputer 61 is activated by the HV controller 80 in addition to the case where the timer 66 is activated when the time period counted by the timer 66 reaches the threshold value Tth. Therefore, the CPU 62 determines whether or not the current activation is due to the timer 66, in other words, whether or not a signal indicating that the stop period has reached the threshold value Tth is received from the timer 66.

  When the CPU 62 receives a signal indicating that the stop period has reached the threshold value Tth from the timer 66, the CPU 62 determines that there is a notification from the timer 66 (S50: YES), drives the electric oil pump 46, and A process of sucking the lubricating oil in the pan 44 and discharging it to the engine body 42 side is executed (S52). Here, processing for feedback control of the rotational speed Nm of the electric motor 46a to the target rotational speed is executed. This process is continued for a predetermined period (S54: NO). Here, the predetermined period is set to a time required for mixing the lubricating oil and water to make it difficult to separate the water from the lubricating oil.

  And CPU62 stops the electric oil pump 46, when a predetermined period passes (S54: YES) (S56). Note that when the process of step S56 is completed or when a negative determination is made in step S50, the CPU 62 once ends the series of processes shown in FIG. Incidentally, when the processing of steps S52 to S56 is completed after the microcomputer 61 is activated, the microcomputer 61 switches itself to the OFF state after executing the processing shown in FIG.

Here, the operation of the present embodiment will be described.
When the internal combustion engine 40 is driven for a short time and stopped at a timing when the temperature of the lubricating oil does not reach the boiling point of water, water is mixed into the lubricating oil. When the internal combustion engine 40 is stopped, the CPU 62 sets the timer 66 when the moisture amount DW is equal to or greater than the specified amount DWth. As a result, the timer 66 starts a time counting operation during the stop period of the electric oil pump 46. This timing operation is continued regardless of whether the microcomputer 61 is in the off state or the on state. Further, the operation is continued regardless of whether or not the SMR 24 is closed and the vehicle is allowed to travel. When the timer 66 reaches the threshold value Tth, the timer 66 activates the microcomputer 61 and notifies the CPU 62 to that effect. Thereby, CPU62 performs the stirring process which stirs lubricating oil and water by driving the electric oil pump 46 (S52). Here, the stirring process is executed regardless of whether the SMR 24 is in a closed state or an open state. In other words, it is executed regardless of whether or not the vehicle is ready to travel. Further, it is executed regardless of whether or not the user is on board, and is executed even when the user is not on board and the door of the vehicle is in a locked state. Thereby, it can suppress that water isolate | separates from lubricating oil.

According to the present embodiment described above, the following effects can be further obtained.
(1) Since the timer 66 is set on the condition that the moisture amount DW is equal to or greater than the specified amount DWth, it is possible to avoid the timer 66 from performing a timing operation unnecessarily.

<Second Embodiment>
Hereinafter, the second embodiment will be described with reference to the drawings with a focus on differences from the first embodiment.

In the present embodiment, the threshold value Tth is variably set according to the moisture content DW, the degree of deterioration of the lubricating oil, and the average temperature Tave.
FIG. 5 shows a procedure for calculating the deterioration parameter Doil for quantifying the deterioration degree of the lubricating oil. The processing shown in FIG. 5 is realized by the CPU 62 executing the program stored in the memory 64. The process shown in FIG. 5 is repeatedly executed at a predetermined cycle, for example. The deterioration parameter Doil is set to a larger value as the deterioration degree is larger.

  In the series of processes shown in FIG. 5, the CPU 62 first determines whether or not the internal combustion engine 40 is being driven (S60). And when determining with driving | running | working (S60: YES), CPU62 acquires rotational speed NE (S62), and acquires cooling water temperature THW (S64). Next, the CPU 62 calculates the deterioration update amount ΔDoil according to the rotational speed NE and the coolant temperature THW, and updates the deterioration parameter Doil by adding the deterioration update amount ΔDoil to the deterioration parameter Doil (S66).

  Here, even when the cooling water temperature THW is the same, the deterioration update amount ΔDoil is set to a larger value than when it is low when the rotational speed NE is high. This is because, firstly, the higher the oil temperature Toil, the more the deterioration of the lubricating oil is promoted, and the oil temperature Toil is higher when the rotational speed NE is higher than when it is low. Secondly, when the rotational speed NE is high, the shearing force exerted on the lubricating oil at the sliding portion of the engine body 42 becomes larger than when the rotational speed NE is low, so that deterioration of the lubricating oil is promoted. Further, the deterioration update amount ΔDoil is set to a larger value when the cooling water temperature THW is high than when it is low even if the rotational speed NE is the same. This is because the deterioration of the lubricating oil is promoted as the oil temperature Toil is higher, and the oil temperature Toil is higher when the cooling water temperature THW is higher than when it is low. Specifically, a two-dimensional map having the rotational speed NE and the coolant temperature THW as input variables and the deterioration update amount ΔDoil as an output variable is stored in the memory 64, and the deterioration update amount ΔDoil is calculated using this map.

  When the process of step S66 is completed or when a negative determination is made in step S60, the CPU 62 once ends the series of processes shown in FIG. Incidentally, the deterioration parameter Doil is reset when it is replaced with a new lubricating oil. For example, this can be realized by inputting a signal to that effect to the control device 60 when the dealer replaces with new lubricant.

  FIG. 6 shows a procedure for estimating the average temperature Tave. The processing shown in FIG. 6 is realized by the CPU 62 executing a program stored in the memory 64. The process shown in FIG. 6 is executed with the start of the microcomputer 61 as a trigger. Note that the average temperature Tave is a value obtained by roughly estimating the average value of the temperature in a period having a length of about the threshold value Tth from the present time by estimating the average temperature of the day on the estimation date.

  In the series of processes shown in FIG. 6, the CPU 62 acquires the current time to and the outside air temperature THO (S72). Here, the current time to may be realized by providing a clock in the microcomputer 61, for example. Then, the CPU 62 predicts the average temperature Tave based on the outside temperature THO and the current time to (S74).

  Here, when the outside temperature THO is low, the CPU 62 sets the average temperature Tave to a lower value than when the outside temperature THO is high, and when the outside temperature THO is the same, the CPU 62 increases the average temperature Tave as the current time to becomes closer to noon. Set to a lower value. This is a setting in view of the fact that the average temperature Tave is considered to be lower than the daytime outside temperature THO. Here, even if the outside temperature THO is the same, the current time to when the average temperature Tave is the lowest value may be, for example, 2:00 noon. Specifically, a two-dimensional map having the outside temperature THO and the current time to as input variables and the average temperature Tave as an output variable is stored in the memory 64, and the CPU 62 calculates the average temperature Tave using this map. To do.

In addition, when the process of step S74 is completed, CPU62 once complete | finishes a series of processes shown in FIG.
FIG. 7 shows the procedure of the timer 66 setting process. The processing shown in FIG. 7 is realized by the CPU 62 executing a program stored in the memory 64. The process shown in FIG. 7 is repeatedly executed at a predetermined cycle, for example. Of the processes shown in FIG. 7, processes corresponding to the processes shown in FIG. 3 are given the same step numbers for the sake of convenience, and detailed description thereof is omitted.

  In the series of processes shown in FIG. 7, when affirmative determination is made in step S <b> 32, the CPU 62 acquires the deterioration parameter Doil (S <b> 80) and acquires the average temperature Tave in addition to the acquisition of the moisture amount DW (S <b> 34). (S82). If the CPU 62 determines that the moisture amount DW is equal to or greater than the specified amount DWth (S36: YES), the CPU 62 variably sets the threshold value Tth (S84).

  Here, when the average temperature Tave and the deterioration parameter Doil are the same, the CPU 62 sets the threshold value Tth to a smaller value when the moisture amount DW is large than when the moisture amount DW is small. This is a setting in view of the fact that water is more easily separated from the lubricating oil when the amount of water DW is large than when it is small. In addition, when the moisture amount DW and the average temperature Tave are the same, the CPU 62 sets the threshold value Tth to a smaller value when the deterioration parameter Doil is large than when it is small. This is a setting in view of the fact that water is more easily separated from the lubricating oil when the degree of deterioration is large than when it is small. When the moisture amount DW and the deterioration parameter Doil are the same, the CPU 62 sets the threshold value Tth to a smaller value when the average temperature Tave is low than when it is high. This is because water is more easily separated from the lubricating oil when the temperature of the lubricating oil is low than when it is high, whereas the temperature of the lubricating oil when the internal combustion engine 40 is stopped is higher than when the average temperature Tave is low. This is a setting in view of the fact that it is considered to be low. Specifically, a three-dimensional map having the moisture content DW, the deterioration parameter Doil, and the average temperature Tave as input variables and the threshold value Tth as an output variable is stored in the memory 64, and the CPU 62 uses this map to set the threshold value. Tth is calculated. Incidentally, the map stores a value equal to or less than the assumed maximum amount contained in the lubricating oil with respect to the moisture amount DW which is one of the input variables.

After setting the threshold value Tth, the CPU 62 proceeds to the process of step S38.
Here, for example, when the threshold value Tth is set as a fixed value so that the agitation process is performed before the separation of water from the lubricating oil becomes significant when the moisture amount DW is equal to or greater than the specified amount DWth, When the moisture amount DW is greater than or less than the specified amount DWth, there is a concern that the stirring process is executed when it is still too early to perform the stirring process. In addition, when the deterioration parameter Doil is large, when the threshold value Tth is set as a fixed value so that the agitation process is performed before the separation of water from the lubricating oil is not significant, the deterioration parameter Doil is still small. There is a concern that the stirring process is executed when it is too early to perform the stirring process. Furthermore, when the average temperature Tave is low, when the threshold value Tth is set as a fixed value so that the agitation processing is performed before the separation of water from the lubricating oil becomes not significant, when the average temperature Tave is high, it is still There is a concern that the stirring process is executed when it is too early to perform the stirring process.

  On the other hand, in the present embodiment, by setting the threshold value Tth variably, it is possible to delay the execution of the process of step S52 as much as possible while suppressing the separation of water from the lubricating oil from being significant. As a result, the execution opportunity of the process of step S52 can be reduced. For this reason, the amount of energy consumption can be reduced.

<Third Embodiment>
Hereinafter, the third embodiment will be described with reference to the drawings with a focus on differences from the second embodiment.

  According to the second embodiment, it is considered that the process of step S52 is basically performed in winter. This is because when the outside air temperature THO is high as in summer, the oil temperature Toil is likely to rise, so that the oil temperature Toil easily reaches the boiling point of water even if the driving time of the internal combustion engine 40 is short. However, for example, even when the lubricating oil contains water of a specified amount DWth or more in the winter season, even when the water is separated from the lubricating oil, the suction port 50 is not clogged. Regardless, when the internal combustion engine 40 is in a stopped state for a long period of time, there is a concern that the state in which the amount of water in the lubricating oil is equal to or greater than the specified amount DWth continues. In that case, even when water is separated from the lubricating oil, even when it is a season when the suction port 50 is not likely to be clogged, the electric oil pump 46 is stopped by reaching the threshold value Tth. There is a concern that the oil pump 46 is driven. This embodiment addresses this concern.

  FIG. 8 shows the procedure of the timer 66 setting process. The processing shown in FIG. 8 is realized by the CPU 62 executing the program stored in the memory 64. The process shown in FIG. 8 is repeatedly executed at a predetermined cycle, for example. Of the processes shown in FIG. 8, processes corresponding to the processes shown in FIG. 7 are given the same step numbers for the sake of convenience, and detailed description thereof is omitted.

  In the series of processing shown in FIG. 8, the CPU 62 performs variable setting of the threshold Tth (S84) and timer 66 setting processing (S38) on condition that the average temperature Tave is equal to or lower than the threshold temperature TthL (S86: YES). Run. That is, when the temperature is higher than the threshold temperature TthL, the series of processing shown in FIG. 8 is temporarily ended, and the threshold Tth variable setting (S84) and the timer 66 setting processing (S38) are not executed. Here, the threshold temperature TthL is set based on an average temperature that is assumed that the lowest temperature in the period of the length of the threshold Tth from the current time can be equal to or lower than the freezing point of water.

According to such a process, it can suppress that the process of step S52 is performed because the water content DW is large in summer.
<Fourth Embodiment>
Hereinafter, the fourth embodiment will be described with reference to the drawings with a focus on differences from the second embodiment.

  FIG. 9 shows the procedure of the timer 66 setting process. The processing shown in FIG. 9 is realized by the CPU 62 executing a program stored in the memory 64. The process shown in FIG. 9 is repeatedly executed at a predetermined cycle, for example. Of the processes shown in FIG. 9, processes corresponding to the processes shown in FIG. 7 are given the same step numbers for the sake of convenience, and detailed description thereof is omitted.

  In the series of processing shown in FIG. 9, when the CPU 62 obtains the moisture amount DW, the deterioration parameter Doil, and the average temperature Tave (S34, S80, S82), the determination value Cth is set (S84a), and the time counting operation is started. Then, the timer 66 is set so as to notify the fact that the timing period reaches the determination value Cth (S38a). Here, the CPU 62 sets the determination value Cth using the moisture amount DW, the deterioration parameter Doil, and a three-dimensional map that defines the relationship between the average temperature Tave and the determination value Cth. Here, when the water content DW as an input variable is a discrete value of the specified amount DWth or more, the three-dimensional map uses the determination value Cth as the water content DW and the deterioration parameter Doil in the third embodiment. And a threshold value Tth that is variably set according to the average temperature Tave. On the other hand, the three-dimensional map determines the determination value Cth as the execution suppression value CL when the moisture amount DW is less than the specified amount DWth. The three-dimensional map includes a value when the value of the moisture amount DW as an input variable is “DWth−Δ” using the minimum unit Δ of the moisture amount DW calculated by the process of FIG. Both are retained at least. Here, the execution suppression value CL is a value larger than the maximum value of the threshold value Tth, which is the threshold value Tth when the moisture amount DW is the specified amount DWth, and specifically, the process of step S52 is intended to be executed. This is a value to avoid. The execution suppression value CL is set to a value larger than the assumed maximum value of the stop period of the internal combustion engine 40 in various cases assumed as how the vehicle is used in the present embodiment. In this embodiment, it is set to any value between 100 and 1000 days, for example.

  The execution suppression value CL is a powerless value for suppressing the possibility of clogging caused by ice at the suction port 50 of the strainer 48. The execution suppression value CL is set to a stop period during which it is not possible to prevent water from freezing and clogging, assuming that water of a specified amount DWth or more is mixed in the lubricating oil. Specifically, the execution suppression value CL is used to suppress clogging even when the lubricating oil contains any amount of water that may cause clogging due to ice at the suction port 50 of the strainer 48. It is set to a helpless value. The time taken for the water to separate from the lubricating oil is determined by experiments depending on the type of the lubricating oil. The execution suppression value CL is longer than the time in which water equal to the specified amount DWth is mixed in the lubricating oil and the amount of water that may be clogged in a freezing point (0 ° C.) environment is separated and frozen.

  Here, when the moisture amount DW is less than the specified amount DWth, it is not assumed in the present embodiment that the lubrication process is hindered. Then, before the period of the execution suppression value CL elapses, it is assumed that the internal combustion engine 40 is driven and the timer 66 is reset, so that the situation where the stirring process is made unnecessary is sufficiently suppressed.

<Fifth Embodiment>
Hereinafter, the fifth embodiment will be described with reference to the drawings, focusing on the differences from the first embodiment.

  FIG. 10 shows a process when the microcomputer 61 (CPU 62) is activated. The processing shown in FIG. 10 is realized by the CPU 62 executing the program stored in the memory 64. This process is executed with the start of the microcomputer 61 as a trigger. In addition, about the process corresponding to the process shown in FIG. 4 among the processes shown in FIG. 10, the same step number is attached for convenience and detailed description is abbreviate | omitted.

  In the series of processes shown in FIG. 10, when the determination in step S50 is affirmative, the CPU 62 rotates the electric motor 46a of the electric oil pump 46 in the reverse direction from when the engine body 42 is lubricated (S52a). Thus, the CPU 62 causes the electric oil pump 46 to suck the fluid on the engine body 42 side and discharge it to the oil pan 44. Specifically, the CPU 62 feedback-controls the rotation speed Nm for reverse rotation to the target rotation speed.

  Here, when the stop period of the electric oil pump 46 becomes long, the lubricating oil flows out through the clearance of the bearing portion of the engine body 42 and the like. For this reason, when the stop period is equal to or greater than the threshold value Tth, the volume in the path is filled in the path positioned on the opposite side of the oil pan 44 from the electric oil pump 46, such as the lubrication path of the engine body 42. Instead of being filled with lubricating oil, the lubricating oil and air are mixed. For this reason, the fluid flowing out from the suction port 50 to the oil pan 44 contains not only lubricating oil but also air. Even when air flows out to the oil pan 44, the lubricating oil in the oil pan 44 is agitated. Depending on the setting of the execution period of the agitation process, all of the lubricating oil in the lubrication path may be exhausted, and at least in the later stage of the agitation process, the fluid discharged from the electric oil pump 46 may be only air.

  As described above, since the electric oil pump 46 discharges at least air-containing fluid, the torque required to drive the electric motor 46a at the same rotational speed is smaller than when only the lubricating oil is discharged. As a result, the power consumption of the electric motor 46a is reduced. For this reason, in this embodiment, compared with the said 1st Embodiment, if the rotational speed Nm of the electric motor 46a and the continuous period of a stirring process are the same, required electric power will become small.

<Correspondence>
Correspondences between the items described in the column of “Means for Solving the Problems” and items in the embodiment are as follows. In the following, “CPU 62 that executes a predetermined process according to a program stored in memory 64” will be referred to as “CPU 62 that executes a predetermined process” in order to simplify the description.

  1. The drive control device corresponds to the control device 60, the agitation processing unit corresponds to the CPU 62 that executes the processing of steps S52 and S54, and the CPU 62 that executes the processing of steps S52a and S54, and the moisture content acquisition processing unit is The timekeeping processing unit corresponds to the timer 66 and corresponds to the CPU 62 that executes the process of step S <b> 34.

2. This corresponds to the first to third and fifth embodiments, and in particular, the specified amount determination processing unit corresponds to the CPU 62 that executes the process of step S36.
3. Corresponding to the fourth embodiment, in particular, the period determination processing unit corresponds to the CPU 62 that executes the process of step S50. That is, when the CPU 62 executes the process of step S38a, the timer 66 notifies the CPU 62 that the stop period has reached the determination value Cth, and the CPU 62 determines that the determination value Cth has been reached by the notification. The determination value variable setting processing unit corresponds to the CPU 62 that executes the process of step S84a. The distribution channel corresponds to the strainer 48.

4). The threshold variable setting processing unit corresponds to the CPU 62 that executes the process of step S84.
5. The deterioration information acquisition processing unit corresponds to the CPU 62 that executes the process of step S80, and the threshold variable setting processing unit corresponds to the CPU 62 that executes the process of step S84.

6). The temperature acquisition processing unit corresponds to the CPU 62 that executes the process of step S82, and the threshold variable setting processing unit corresponds to the CPU 62 that executes the process of step S84.
7). This corresponds to the fifth embodiment (FIG. 10).

<Other embodiments>
In addition, you may change at least 1 of each matter of the said embodiment as follows.
・ "Regular amount judgment processing part"
The prescribed amount determination processing unit is not limited to the determination that the prescribed amount DWth is equal to or greater than the prescribed amount DWth is used as a trigger for timing operation during the stop period. For example, in the first embodiment, when the electric oil pump 46 is switched from the drive state to the stop state, the process of step S38 in FIG. 3 is executed, and the stop period reaches the threshold value Tth by the notification by the timer 66. When the CPU 62 determines, it may be determined whether or not the moisture amount DW is equal to or greater than the specified amount DWth. Note that the process of determining whether or not the moisture amount DW is equal to or greater than the specified amount DWth when the stop period reaches the threshold value Tth is not limited to the threshold value Tth being a fixed value. For example, as described in “About the threshold value variable setting processing unit” below, the threshold value Tth is variably set only by the deterioration parameter Doil and the average temperature Tave, or variable only by one of the deterioration parameter Doil and the average temperature Tave. It may be set.

・ About the threshold variable setting processing unit
The threshold value Tth is not limited to be variably set according to the moisture amount DW, the deterioration parameter Doil, and the average temperature Tave. For example, the threshold value Tth may be variably set based on only two or only one of the moisture amount DW, the degradation parameter Doil, and the average temperature Tave.

・ About stirring process
It is not essential to feedback control the rotational speed Nm of the electric motor 46a to the target rotational speed. For example, the current flowing through the electric motor 46a may be feedback controlled to the target value. In this case, the target value in the process of step S52a of the fifth embodiment is desirably set to a value smaller than the target value in the process of step S52 of the first embodiment. This is because in the fifth embodiment, since the electric oil pump 46 sucks air, the same rotational speed can be realized with a smaller torque than in the first embodiment. In addition to the feedback control, the voltage applied to the electric motor 46a may be an open-loop operation amount, and the rotational speed of the electric motor 46a may be controlled in an open-loop manner.

  For example, as described in the column of “Lubrication of the internal combustion engine” below, a setting in which the amount of the lubricating oil in the lubrication path of the engine body 42 flowing out to the outside as time elapses while the internal combustion engine 40 is stopped can be ignored. In this case, the process of step S52a may not reduce the energy consumption as compared with the process of step S52. However, even in that case, it is possible to suppress the separation of the lubricating oil from the water by executing the process of step S52a. It should be noted that the processing of step S52a can be realized in step S52a when the amount of the lubricating oil in the lubrication path of the engine main body 42 flowing out to the outside as time elapses while the internal combustion engine 40 is in a stopped state can be realized in step S52a This is a case where the lubrication path in the engine main body 42 sucks air from the outside by executing the processing. This includes, for example, a hole that opens vertically above a hole that allows the lubrication path to communicate with the outside, and a check valve that restricts the flow of fluid from the outside to the lubrication path for the other holes. This is possible.

・ "Execution conditions for stirring process"
Making the execution temperature of the stirring process that the average temperature Tave is low can be adopted regardless of variably setting the threshold value Tth as in the third embodiment. That is, you may employ | adopt, for example in 1st Embodiment, 4th Embodiment, and 5th Embodiment.

  Note that the process for setting the low average temperature Tave as the execution condition of the stirring process is not limited to the process of performing the time counting operation of the timer 66 on condition that the average temperature Tave is equal to or lower than the threshold temperature TthL. For example, when the CPU 62 makes an affirmative determination in step S50 of FIG. 4, the process of step S52 is executed on the condition that the average temperature Tave is determined to be equal to or lower than the threshold temperature TthL, and the stop period becomes the threshold Tth. It may be determined whether or not the average temperature Tave is low.

・ "Regulated amount"
In the above embodiment, the specified amount DWth is set to a value that may cause clogging of the suction port 50 when water becomes separated from the lubricating oil and then becomes ice, but is not limited thereto. For example, the value may cause a small amount of ice that can pass through the mesh structure of the suction port 50. Even in this case, for example, a finer filter than the mesh structure is provided on the downstream side of the suction port 50 in the lubricating oil distribution path, and the filter may be clogged due to minute ice. Thus, if there is a possibility that the lubrication process of the engine body 42 may be hindered, it is effective to suppress the generation of minute ice by the stirring process.

・ About the execution suppression value
In the said embodiment, although the execution suppression value CL was set to the value between 100-1000 days, it is not restricted to this. For example, it may be set to a value larger than 1000 days, such as 10,000 days. However, it is not essential that it is 100 days or longer. For example, in a vehicle or the like in which electric power outside the vehicle cannot be charged into the assembled battery 26 as described in the “About vehicle” section below, an internal combustion engine Since the assumed maximum value of the 40 stop periods is considered to be short, it can be set to a value between 30 and 100 days, for example.

・ About setting of judgment value
In the above embodiment, the value when the moisture amount DW as the input variable of the map for determining the determination value Cth is the specified amount DWth is included, but the present invention is not limited to this. For example, when the first predetermined value less than the prescribed amount DWth and the second prescribed value larger than the prescribed amount DWth are set to the value of the input variable closest to the prescribed amount DWth, the moisture amount DW is larger than the first predetermined value and is second. When the value is less than the predetermined value, the determination value Cth may be interpolated. In this case, the value at the specified amount DWth is the threshold value Tth, and the determination value Cth obtained by the interpolation calculation when the moisture amount DW is “DWth + Δ” using the minimum unit Δ for the moisture amount DW is suppressed. It becomes the value CL.

  As in the fourth embodiment, it is not essential to set the variably set threshold value Tth when the moisture amount DW is equal to or greater than the specified amount DWth, and a fixed value is set as in the first embodiment. May be.

・ About the amount of moisture
In the above embodiment, the water content is specified by weight, but the present invention is not limited to this, and may be, for example, the content in the lubricating oil. Here, when the weight Woil of the lubricating oil not containing water is used, the content rate has a relationship of “DW / (DW + Woil)” with the water content DW in the above embodiment, and the specified amount DWth is “DWth / By converting to “(Dwth + Woil)”, the same effect as that of the above embodiment can be obtained. However, for example, when a sensor for detecting the amount of lubricating oil is provided, expressing the amount of water by the content rate is more accurate in grasping that the water in the lubricating oil is separated from the water than in the above embodiment. Parameter.

  The estimation is not limited to those based on the injection amount Q, the coolant temperature THW, and the outside air temperature THO. For example, the moisture amount DW may be calculated only from the injection amount Q by calculating the moisture update amount ΔDW only from the injection amount Q. Further, for example, the moisture amount DW may be calculated from the injection amount Q and the cooling water temperature THW or the outside air temperature THO by calculating the water update amount ΔDW from the injection amount Q and the cooling water temperature THW or the outside air temperature THO.

Moreover, you may utilize the detection value of the sensor which detects a moisture content based on the reflected wave at the time of irradiating an ultrasonic wave to lubricating oil.
・ "Deterioration degree information"
The estimation method of the degradation parameter Doil is not limited to the method exemplified in the above embodiment. For example, the deterioration parameter Doil may be estimated by providing a sensor that detects the temperature of the lubricating oil and sequentially calculating the deterioration update amount ΔDoil from the detected value of the sensor. Alternatively, the deterioration parameter Doil may be estimated by sequentially calculating the deterioration update amount ΔDoil from the detected temperature value and the rotation speed.

  The information on the degree of deterioration may be binary information indicating whether or not the deterioration has occurred. This is, for example, information generated by determining whether the degree of deterioration is large or the degree of deterioration is small, depending on whether the vehicle travel distance from when the lubricant is new is greater than or equal to a specified value. And it is sufficient.

・ About temperature
In the above embodiment, the average temperature Tave is estimated based on the outside temperature THO when the control device 60 is activated and the time (current time to) at the time of activation, but the present invention is not limited to this. For example, the average temperature may be temporarily estimated when the control device 60 is started, and the final average temperature Tave may be estimated by weighted average processing of the temporarily estimated average temperature and the currently held average temperature Tave. . In addition, for example, as described in “Drive control device” below, the average temperature Tave is sequentially calculated by moving average processing from the latest sampling value of the outside temperature THO for each predetermined period to a predetermined number of previous ones. You may make it calculate.

  Moreover, it is not restricted to what estimates average temperature based on outside temperature THO. For example, date information may be acquired, the season may be determined, and the final average temperature may be estimated based on regional information. Further, not only the estimation of the average temperature, but, for example, the temperature in a time zone where the temperature is assumed to be the lowest in one day may be estimated. Even in this case, it is effective to set the threshold value Tth shorter as the temperature is lower.

Furthermore, the temperature included in the weather information in the radio signal obtained from the outside of the vehicle is not limited to the one that estimates the temperature, and the control device 60 may capture the temperature.
・ About resetting the timer
In the above embodiment, when the electric oil pump 46 is driven, the timer is reset regardless of the drive time, but the present invention is not limited to this. For example, when the internal combustion engine 40 stops because the vehicle is parked immediately after the electric oil pump 46 is started as the internal combustion engine 40 is started, the timer 66 is reset in view of insufficient stirring. Instead of this, the time measured until then may be corrected to be shortened, and the time counting operation of the timer 66 may be continued. Thereby, compared with the case where the internal combustion engine 40 is not started, the timing at which the CPU 62 is notified that the threshold value Tth is exceeded is delayed.

・ About timer settings
For example, in the first embodiment, the timer 66 may be configured as follows instead of making it possible to measure the period up to the threshold value Tth. That is, for example, when the maximum timing period of the timer 66 is set to, for example, a predetermined value (for example, 5 days), the timer 66 is set to a predetermined value, and the timer 66 notifies that the predetermined value has elapsed, the CPU 62 The timer 66 is set to a predetermined value again without executing the stirring process. For example, when the threshold value Tth is 14 days, when the timer 66 notifies that the predetermined value has passed again, the CPU 62 sets the timer 66 to 4 days without executing the stirring process. The application of such a technique is not limited to the first embodiment. In particular, since the determination value Cth can be very large in the fourth embodiment, application to the fourth embodiment is effective.

・ About the suspension period
In the above embodiment, the stop period to be compared with the threshold value Tth and the determination value Cth is the stop period of the electric oil pump 46, but is not limited thereto. For example, when the internal combustion engine includes an engine-driven oil pump that is driven by the rotational power of the crankshaft of the internal combustion engine in addition to the electric oil pump, the lubricating oil is used for lubricating the internal combustion engine. The period in which both the engine-driven oil pump and the electric oil pump are stopped is set to a period in which the engine is not stirred by the stirring process.

・ "About lubrication of internal combustion engine"
In the above-described embodiment, the lubricating oil in the lubrication path of the engine body 42 flows out as time passes while the internal combustion engine 40 is stopped, and the engine body 42 is lubricated in a state where the lubricating oil in the path is reduced. No particular mention was made of the request to execute the process. Actually, even if the internal combustion engine 40 is started in a state where the lubricating oil in the path is reduced, the engine body 42 is lubricated while the internal combustion engine 40 is stopped if the setting is such that the reliability of the internal combustion engine 40 can be maintained high. It is possible that a process execution request does not occur. However, in a state where the lubricating oil in the path is reduced, when a request for starting the internal combustion engine 40 is generated, the electric oil pump 46 is driven prior to the start of the internal combustion engine 40 to solve the lack of lubrication and then the internal combustion engine. It is also possible to start 40. In this case, when the electric oil pump 46 is driven prior to the start of the internal combustion engine 40 after the process of step S52a of FIG. 10 is executed once, the process of step S52 of FIG. 4 is executed once. After that, the energy consumption may increase as compared with a case where the electric oil pump 46 is driven. However, when the situation where the electric oil pump 46 is driven prior to the start of the internal combustion engine 40 occurs, when the process of step S52a is executed a plurality of times, compared to when the process of step S52 is executed a plurality of times. It is thought that energy consumption can be reduced.

  In addition, the engine body 42 is lubricated while the internal combustion engine 40 is stopped even in a setting where the amount of lubricating oil in the lubrication path of the engine body 42 flowing out to the outside as time elapses while the internal combustion engine 40 is stopped. It is possible that a process execution request does not occur.

・ About the strainer
It is not essential that the suction port 50 is disposed to face the bottom of the oil pan 44. For example, even if the suction port 50 faces vertically upward, if the water in the lubricating oil is solidified and then solidified, there is no doubt that the suction port 50 may be clogged by solidified ice. .

  It is not essential that the suction port 50 has a mesh structure. For example, a mesh structure may be provided in the passage between the suction port 50 and the suction side of the electric oil pump 46. Further, the filter may be provided on the discharge port side of the electric oil pump 46 as a filtering member without having a mesh structure on the upstream side of the electric oil pump 46.

・ About the drive control device
In the above-described embodiment, the timer 61 that continues the time measuring operation even when the microcomputer 61 is in the off state is provided, and the microcomputer 61 is activated when the stop period of the electric oil pump 46 becomes the threshold value Tth or the determination value Cth. Not limited to this. For example, apart from the CPU that executes the control processing of the control amount of the internal combustion engine 40, a CPU that is always on even when the main power supply of the control device 60 is off is provided, whereby FIG. Processes corresponding to the processes in FIGS. 5 and 7 to 10 may be executed. Here, the execution conditions of the processing described in FIG. 4 and FIG. 10 are changed to a predetermined cycle. In the case of this configuration, instead of the process of FIG. 6, the process of calculating the average temperature Tave by the moving average process from the latest sampling value of the outside temperature THO for each predetermined cycle to the predetermined number of samples. Should be executed. In the case of this configuration, instead of the timer 66, the time counting processing unit may be configured by the CPU incrementing the counter at a predetermined period.

  In the above embodiment, the control device 60 includes the CPU 62 and the memory 64 and performs the software processing of the processes of FIGS. 2 to 10, but is not limited thereto. For example, the processing of FIG. 2 and the processing of step S84 of FIG. 7 are provided with an ASIC that executes at least a part of the processing, such as processing with dedicated hardware (application-specific integrated circuit: ASIC). May be.

  In the above embodiment, the drive control device is configured by the control device 60. However, the present invention is not limited to this, and for example, the HV control device 80 executes the processing of steps S32 to S36 in FIG. The drive control device may be configured by both the control device 80 and the control device 80. In this case, when the microcomputer 61 is activated by the timer 66 when the HV control device 80 is in the off state, the control device 60 executes processing for starting the HV control device 80, and the HV control device 80 When an affirmative determination is made in S36, this is notified to the control device 60.

・ About the vehicle
The hybrid vehicle is not limited to a so-called plug-in hybrid vehicle that can charge the assembled battery 26 with electric power from outside the vehicle. Even if the battery pack 26 has a small capacity such as a battery that cannot be charged with electric power outside the vehicle, for example, when the internal combustion engine 40 is driven for a short time in a cold region and then left to stand, Since the lubricating oil is left with moisture contained therein, it is effective to perform the stirring process.

Not limited to series / parallel hybrid vehicles. For example, a parallel hybrid vehicle or a series hybrid vehicle may be used.
However, not only the hybrid vehicle, but even if the engine that powers the drive wheels is only the internal combustion engine, if the internal combustion engine stops after traveling a short distance in a cold region, the lubricating oil contains moisture. If a very rare case of leaving for a long time after that occurs, water may be separated from the lubricating oil. For this reason, it may be effective to perform the stirring process.

  DESCRIPTION OF SYMBOLS 10 ... Power split mechanism, 12, 14 ... Motor generator, 16 ... Drive wheel, 18, 20 ... Inverter, 22 ... DCDC converter, 24 ... SMR, 26 ... Battery pack, 28 ... Charger, 30 ... Commercial power supply, 40 ... Internal combustion engine, 42 ... Engine body, 44 ... Oil pan, 46 ... Electric oil pump, 46a ... Electric motor, 48 ... Strainer, 50 ... Suction port, 60 ... Control device, 61 ... Microcomputer, 62 ... CPU, 64 ... Memory, 66 ... Timer, 70 ... Rotational speed sensor, 72 ... Water temperature sensor, 74 ... Outside air temperature sensor, 76 ... Motor rotation sensor, 80 ... HV controller, 82 ... Power switch, 84 ... Auxiliary battery.

Claims (7)

In a drive control device for an electric oil pump that drives an electric oil pump for sucking the lubricating oil from a suction port immersed in the lubricating oil in an oil pan and using it for lubricating an internal combustion engine,
An agitation processing unit for executing an agitation process for agitating the lubricating oil in the oil pan by driving the electric oil pump while the internal combustion engine is stopped;
A moisture content acquisition processing unit for acquiring the moisture content in the lubricating oil;
A timing processing unit that counts a stop period that is a period in which the lubricating oil is not utilized for lubrication of the internal combustion engine and is not stirred by the stirring processing unit,
When the water content acquired by the water content acquisition processing unit is equal to or greater than a predetermined amount, the stirring processing unit is configured so that the stop period timed by the time processing unit reaches a threshold value. The drive control apparatus of the electric oil pump characterized by performing this. A specified amount determination processing unit that determines whether or not the amount of water estimated by the moisture amount acquisition processing unit is equal to or greater than the specified amount;
The drive control device for an electric oil pump according to claim 1, wherein the agitation processing unit does not execute the agitation process when the specified amount determination processing unit determines that the amount is less than the specified amount. A period determination processing unit that determines whether or not the stop period timed by the timing processing unit has reached a determination value;
The determination value is set to the same value as the threshold when the amount of water is equal to or greater than the specified amount, and the determination value is set to an execution suppression value that is greater than the threshold when the amount of water is less than the specified amount. A judgment value variable setting processing unit,
The agitation processing unit performs the agitation processing on the condition that the period determination processing unit determines that the stop period has reached the determination value,
The threshold value is set to a value for suppressing the possibility of clogging caused by ice in the flow path of the lubricating oil sucked from the oil pan by the electric oil pump,
2. The electric motor according to claim 1, wherein the execution suppression value is set to an ineffective value for suppressing a risk of clogging caused by ice in a flow path of lubricating oil sucked from the oil pan by the electric oil pump. Oil pump drive control device.   When the water content acquired by the water content acquisition processing unit is equal to or more than the specified amount, a variable threshold setting processing unit is provided for setting the threshold value to a smaller value when the water content is high than when the water content is low. The drive control apparatus of the electric oil pump of 2 or 3. A deterioration information acquisition processing unit for acquiring deterioration degree information of the lubricating oil;
4. The electric motor according to claim 2, further comprising: a threshold value variable setting processing unit that sets the threshold value to a smaller value based on the information acquired by the deterioration information acquisition processing unit than when the deterioration degree is large. Oil pump drive control device. A temperature acquisition processing unit for acquiring the temperature;
The drive control apparatus for an electric oil pump according to claim 2 or 3, further comprising a threshold variable setting processing unit that sets the threshold to a smaller value than when the temperature acquired by the temperature acquisition processing unit is low. .   The agitation process is a process of discharging the fluid sucked from the discharge side of the electric oil pump when the internal combustion engine is lubricated to the oil pan from the suction side of the electric oil pump when the internal combustion engine is lubricated. The drive control apparatus for an electric oil pump according to any one of claims 1 to 6.

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