阅读说明：本技术 电动车辆的发动机控制装置 (Engine control device for electric vehicle ) 是由 天野贵士 小笠原康二 于 2020-08-19 设计创作，主要内容包括：本发明提供一种能够同时实现减少颗粒状物质的颗粒数和低NV化的电动车辆的发动机控制装置。电动车辆具备：旋转电机,所述旋转电机产生驱动车轮的驱动力；蓄电装置,所述蓄电装置蓄积向旋转电机供给的电力；发电机,所述发电机产生对蓄电装置进行充电的电力；以及发动机,所述发动机产生驱动发电机的驱动力,所述电动车辆的发动机控制装置具备发动机控制单元,所述发动机控制单元决定发动机转速和发动机转矩并控制发动机,从而使从发动机向大气中排放的每单位气体量的颗粒状物质的颗粒数成为目标值以下,并且在车速小于阈值时,与车速为阈值以上时相比,使发动机转速成为低转速,所述目标值是与发动机的预热状态、发动机转速以及发动机转矩建立对应而设定的值。(The invention provides an engine control device for an electric vehicle, which can reduce the number of particles of particulate matter and reduce NV. The electric vehicle is provided with: a rotary electric machine that generates a driving force that drives a wheel; a power storage device that stores electric power supplied to the rotating electric machine; a generator that generates electric power that charges an electrical storage device; and an engine that generates a driving force for driving the generator, wherein the engine control device of the electric vehicle includes an engine control unit that determines an engine speed and an engine torque and controls the engine such that the number of particles of the particulate matter per unit gas amount discharged from the engine into the atmosphere becomes equal to or less than a target value, and when the vehicle speed is less than a threshold value, the engine speed becomes lower than when the vehicle speed is equal to or greater than the threshold value, the target value being a value set in correspondence with a warm-up state of the engine, the engine speed, and the engine torque.)

1. An engine control device for an electric vehicle, the electric vehicle comprising: a rotary electric machine that generates a driving force that drives a wheel; a power storage device that stores electric power supplied to the rotating electric machine; a generator that generates electric power that charges the electrical storage device; and an engine that generates a driving force that drives the generator,

the engine control device for an electric vehicle is characterized in that,

the engine control device is provided with an engine control means for determining an engine speed and an engine torque and controlling the engine so that the number of particles of particulate matter per unit gas amount discharged from the engine into the atmosphere becomes equal to or less than a target value, and when a vehicle speed is less than a threshold value, the engine speed becomes lower than when the vehicle speed is equal to or greater than the threshold value, the target value being a value set in association with a warm-up state of the engine, the engine speed, and the engine torque.

2. The engine control device of the electric vehicle according to claim 1, wherein the engine control unit allows the intermittent operation of the engine when the engine is in a state hotter than a prescribed warm-up state.

3. The engine control device of the electric vehicle according to claim 2, wherein the engine control unit stops the operation of the engine when the vehicle speed is less than the threshold value and performs the operation of the engine when the vehicle speed is equal to or greater than the threshold value, when the intermittent operation of the engine is permitted.

4. The engine control device of the electric vehicle according to any one of claims 1 to 3, wherein the engine control means determines the engine speed and the engine torque based on a map that is created for each warm-up state of the engine and that shows a relationship between the engine speed and the engine torque that are the target values.

5. The engine control device of the electric vehicle according to any one of claims 1 to 4, characterized in that the engine control unit determines the warm-up state of the engine based on a temperature of a coolant that cools the engine, a temperature of engine oil, an engine integrated air amount, a total engine operation time, or a vehicle travel distance when the engine is operated.

Technical Field

The present invention relates to an engine control device for an electric vehicle.

Background

Conventionally, in an Electric Vehicle such as a REEV (Range Extended Electric Vehicle), when the SOC (State Of Charge) Of a battery is lowered during running, an engine is started and power generation is started by a generator to Charge the battery. In the electric vehicle, since the starting frequency of the engine is low, the engine is not sufficiently warmed up during running, the engine is cooled at the time of starting the engine, and the fuel is often in an environment where the fuel is hard to vaporize. Therefore, in the above-described environment, if the output of the engine is increased to such an extent that the power generation by the generator is possible, the Number of particles (PN: particle Number) of the Particulate matter discharged from the engine into the atmosphere may increase.

Patent document 1 discloses the following technique: the engine control device reduces the number of particles of the particulate matter by performing control to move the operating point of the engine to a high rotation speed and low torque side corresponding to the same required power as compared with a fuel efficiency line in which fuel efficiency is important, during a cold operation of the engine.

Documents of the prior art

Patent document

Patent document 1 Japanese patent laid-open publication No. 2017-137773

Disclosure of Invention

Problems to be solved by the invention

However, in the technique disclosed in patent document 1, in order to reduce the number of particles of the particulate matter, if the engine speed is set to a high speed, NV (Noise Vibration) performance is deteriorated. Therefore, a technique is desired which achieves both reduction in the number of particles of the particulate matter and reduction in NV.

The present invention has been made in view of the above problems, and an object thereof is to provide an engine control device for an electric vehicle capable of reducing the number of particles of particulate matter and reducing NV at the same time.

Means for solving the problems

In order to solve the above problems and achieve the object, an engine control device for an electric vehicle according to the present invention is an engine control device for an electric vehicle including: a rotary electric machine that generates a driving force that drives a wheel; a power storage device that stores electric power supplied to the rotating electric machine; a generator that generates electric power that charges the electrical storage device; and an engine that generates a driving force for driving the generator, wherein the engine control means determines an engine speed and an engine torque, and controls the engine such that the number of particles of the particulate matter per unit gas amount discharged from the engine into the atmosphere becomes equal to or less than a target value, and when a vehicle speed is less than a threshold value, the engine speed becomes lower than when the vehicle speed is equal to or greater than the threshold value, the target value being a value set in correspondence with a warm-up state of the engine, the engine speed, and the engine torque.

In the above, the engine control unit may allow the intermittent operation of the engine when the engine is in a state hotter than a predetermined warm-up state.

This reduces the number of particles of particulate matter per unit gas amount, and achieves a reduction in NV due to intermittent operation of the engine.

In the above configuration, the engine control unit may stop the operation of the engine when the vehicle speed is less than the threshold value and perform the operation of the engine when the vehicle speed is equal to or greater than the threshold value, when the intermittent operation of the engine is permitted.

Thus, the operation of the engine can be stopped at a low vehicle speed, and the NV can be reduced.

In the above configuration, the engine control unit may determine the engine speed and the engine torque based on a map that is created for each warm-up state of the engine and that shows a relationship between the engine speed and the engine torque that are the target values.

This makes it possible to easily determine the engine speed and the engine torque according to the warm-up state of the engine.

In the above, the engine control unit may determine the warm-up state of the engine based on a temperature of a coolant that cools the engine, a temperature of engine oil, an integrated engine air amount, a total engine operating time, or a vehicle travel distance during engine operation.

This makes it possible to easily determine the warm-up state of the engine.

Effects of the invention

The present invention provides an engine control device for an electric vehicle, which can achieve the effects of reducing the number of particles of particulate matter and reducing NV.

Drawings

Fig. 1 is a block diagram showing a configuration of an electric vehicle to which an engine control device of the electric vehicle according to the embodiment is applied.

Fig. 2 is a graph showing a relationship among engine torque, PN per unit gas amount, and water temperature of the engine when the engine speed is 1200[ rpm ].

Fig. 3 is a graph showing a relationship among engine torque, PN per unit gas amount, and water temperature of the engine in the case where the engine speed is 2000 rpm.

FIG. 4(a) is a graph showing an example of an equal PN line at a water temperature of T2[ ° C ], and FIG. 4(b) is a graph showing an example of an equal PN line at a water temperature of T4[ ° C ].

Fig. 5 is a diagram showing an example of a power generation map that defines a relationship between the engine speed and the engine torque when the water temperature of the engine 2 is T2[ ° c and T4[ ° c ].

Fig. 6 is a diagram showing an example of a power generation map defining a relationship between the vehicle speed and the engine speed in the first engine intermittent operation mode.

Fig. 7 is a time chart showing changes in the engine speed, the water temperature of the engine 2, and the SOC of the battery 5 in the first engine intermittent operation mode.

Fig. 8 is a diagram showing an example of a power generation map defining a relationship between the vehicle speed and the engine speed in the second engine intermittent operation mode.

Fig. 9 is a time chart showing changes in the engine speed, the water temperature of the engine 2, and the SOC of the battery 5 in the second engine intermittent operation mode.

Fig. 10 is a flowchart showing an example of control for selecting a power generation map according to the warm-up state of the engine.

Fig. 11 is a flowchart showing an example of control for selecting a power generation map according to the warm-up state of the engine and changing the operating point of the engine in accordance with a change in the SOC of the battery.

Detailed Description

Hereinafter, an embodiment of an engine control device for an electric vehicle according to the present invention will be described. The present invention is not limited to the present embodiment. An electric vehicle to which the engine control device of the present invention is applied is a REEV or the like including an engine for power generation and a motor generator for running, and runs only by a driving force from the motor generator.

Fig. 1 is a block diagram showing a configuration of an electric vehicle 1 to which an engine control device 20 of the electric vehicle 1 according to the embodiment is applied to the electric vehicle 1. The electric vehicle 1 includes an engine 2, a generator 3, a PCU (Power Control Unit) 4, a battery 5, a motor generator 6, a differential device 7, a drive wheel 8, a water temperature sensor 10, an engine Control device 20, and the like.

The engine 2 is an internal combustion engine such as a gasoline engine or a diesel engine, and outputs a driving force for driving the generator 3.

The generator 3 generates electric power by the driving force output from the engine 2. The electric power generated by the generator 3 is supplied to the battery 5 or the motor generator 6 via the PCU 4.

PCU4 has a function of converting dc power supplied from battery 5 into ac power and supplying it to motor generator 6, or converting ac power generated by generator 3 and motor generator 6 into dc power and supplying it to battery 5.

The battery 5 is a power storage device including a secondary battery such as a nickel-metal hydride battery or a lithium ion battery. The battery 5 can be charged with electric power supplied from an external power supply via the plug 9, in addition to electric power generated by the generator 3 and the motor generator 6. The battery 5 is not limited to a secondary battery, and may be a capacitor or the like as long as it is a power storage device that can generate a dc voltage and can be charged.

The motor generator 6 is, for example, a three-phase ac rotating electrical machine. Motor generator 6 outputs a driving force for driving wheels 8 via differential device 7 by using electric power supplied from generator 3 and battery 5 via PCU 4. The motor generator 6 also functions as a generator for generating electric power when the electric vehicle 1 is braked. The electric power generated by the motor generator 6 is supplied to the battery 5 via the PCU 4.

The water temperature sensor 10 is water temperature detection means for detecting the temperature of cooling water, which is coolant for cooling the engine 2 (hereinafter, referred to as the water temperature of the engine 2).

The engine control device 20 is composed of a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and the like. The ROM stores a plurality of power generation maps, which are prepared in advance for each warm-up state of the engine 2 and show the relationship between the engine speed and the engine torque that is a target value of PN per unit gas amount. The unit gas amount is a certain amount of exhaust gas discharged from the engine 2 to the atmosphere. The engine control device 20 determines the engine speed and the engine torque of the engine 2 based on the water temperature information from the water temperature sensor 10, the vehicle speed information from a vehicle speed sensor, not shown, the map for power generation stored in the ROM, and the like, and controls the engine 2.

The electrically powered vehicle 1 according to the embodiment has a plurality of travel modes including a CD mode (Charge depletion) in which the electric power of the battery 5 is consumed and a CS mode (Charge conservation) in which the generator 3 generates electric power by operating the engine 2 to maintain the amount of stored electric power of the battery 5. In the electrically powered vehicle 1, when the running mode is the CD mode, the opportunity to operate the engine 2 is suppressed compared to when the running mode is the CS mode, and fuel efficiency and NV can be reduced.

Fig. 2 is a graph showing a relationship among engine torque, PN per unit gas amount, and water temperature of the engine 2 when the engine speed is 1200[ rpm ]. Fig. 3 is a graph showing a relationship among engine torque, PN per unit gas amount, and water temperature of the engine 2 in the case where the engine speed is 2000 rpm. In fig. 2 and 3, the temperature of the cooling water for cooling the engine 2 (hereinafter referred to as the water temperature of the engine 2), T1[ ° c ], T2[ ° c ], T3[ ° c ], T4[ ° c ], and T5[ ° c ], satisfies the relationship of T1[ ° c ] < T2[ ° c ] < T3[ ° c ] < T4[ ° c ] < T5[ ° c ].

As can be seen from fig. 2 and 3, PN per unit gas amount tends to decrease as the water temperature of the engine 2 increases and as the engine torque increases, regardless of whether the engine speed is 1200 rpm or 2000 rpm. In particular, when the water temperature of the engine 2 reaches T5[ ° c ], PN per unit gas amount is extremely small regardless of the engine speed and the engine torque.

Therefore, in the electrically powered vehicle 1 of the embodiment, in the CS mode, until the warm-up state of the engine 2 satisfies the predetermined state, in other words, until the water temperature of the engine 2 reaches the target water temperature described later, the engine control device 20 controls the engine speed and the engine torque so that PN per unit gas amount becomes equal to or less than the target value. That is, when the generator 3 generates power in the CS mode, the engine control device 20 selects the power generation map stored in the ROM in accordance with the warm-up state of the engine 2, and controls the engine speed and the engine torque. In this case, the engine speed and the engine torque according to the warm-up state of the engine 2 can be easily determined from the power generation map by using the power generation map.

In the electrically powered vehicle 1 of the embodiment, the engine control device 20 determines the warm-up state of the engine 2 based on the water temperature of the engine 2, which is the detection result of the water temperature sensor 10. This makes it possible to easily determine the warm-up state of the engine 2. The determination of the warm-up state of the engine 2 may be performed using, for example, the temperature of engine oil, the integrated engine air amount, the total engine operating time, or the vehicle travel distance during engine operation. The target water temperature of the engine 2 may be determined experimentally in advance, and may be, for example, about 50 to 70 degrees centigrade, and more preferably 60 degrees centigrade, of the water temperature of the engine 2 at the time of completion of warm-up of the engine 2.

FIG. 4(a) is a graph showing an example of the equal PN line at the water temperature T2[ ° C ]. FIG. 4(b) is a graph showing an example of the equal PN line at the water temperature T4[ ° C ].

The equal PN line L1 at the water temperature T2 [. degree.C. ] shown in FIG. 4(a) is the same as the PN per unit gas amount of the equal PN line L3 at the water temperature T4 [. degree.C. ] shown in FIG. 4 (b). The equal PN line L2 at the water temperature T2[ ° c ] shown in fig. 4(a) is the same as the PN per unit gas amount of the equal PN line L4 at the water temperature T4[ ° c ] shown in fig. 4 (b). As is clear from fig. 4(a) and 4(b), when the water temperature of the engine 2 increases, the same iso-PN line per PN of the unit gas amount shifts toward the high engine torque side.

Here, an example of the case where the engine 2 is operated so that the engine output is the same and PN per unit gas amount is the same at the water temperature T2[ ° c ] and the water temperature T4[ ° c ] will be described. In fig. 4(a) and 4(b), the target equal PN lines for which PN per unit gas amount is a target value are equal PN line L1 at water temperature T2[ ° c ] and equal PN line L3 at water temperature T4[ ° c ]. Further, test traveling may be performed in advance under a plurality of traveling conditions including the WLTC mode or the like so that the cumulative PN between the water temperature of the engine 2 and the target water temperature at which warm-up of the engine 2 is completed is equal to or less than a set value, and a target equal PN line may be determined based on the result.

The operating point of the engine 2 at the same engine speed as the operating point P1 on the equal PN line L3 at the water temperature T4[ ° c ] and the equal PN line L1 at the water temperature T2[ ° c ] is the operating point P2 shown in fig. 4 (b). Further, an equal power line L5 of the engine output equal to the operating point P1 of the engine 2 on the equal PN line L1 at the water temperature T2[ deg.C ] and an equal PN line L3 at the water temperature T4[ deg.C ] intersect on the low engine speed side lower than the operating point P2.

When the water temperature T2[ ° c ] and the water temperature T4[ ° c ] are equal, the operating point of the engine 2 is moved along the equal power line L5 from the operating point P1 to the operating point P3, where the operating point P3 is the intersection of the equal power line L5 and the equal PN line L3, and the engine output is made equal to PN per unit gas amount. Thus, the engine 2 can be operated so that the engine output becomes equal to PN per unit gas amount at the water temperature T2[ ° c ] and the water temperature T4[ ° c ]. At this time, by setting the operating point of the engine 2 from the operating point P1 to the operating point P3, the water temperature T4[ ° c ] is higher in engine torque and lower in engine speed than the water temperature T2[ ° c ]. Therefore, at the water temperature T4[ ° C ], the engine speed is reduced as compared to at the water temperature T2[ ° C ], and accordingly, NV can be reduced.

When the water temperature T4[ ° c ] is set such that PN per unit gas amount is less than the equal PN line L3, the operating point on the engine torque side may be set lower than the equal PN line L3. For example, when the PN per unit gas amount is reduced by making the engine output equal to the operating point P1 of the water temperature T2[ ° c ], the operating point on the low engine torque side lower than the operating point P3 on the equal power line L5, for example, the operating point at which the equal power line L5 intersects the equal PN line L4, may be used.

Fig. 5 is a diagram showing an example of a power generation map that defines a relationship between the engine speed and the engine torque when the water temperature of the engine 2 is T2[ ° c and T4[ ° c). In addition, the equal PN line L6 at the water temperature T2[ ° C ] shown in FIG. 5 is the same as the PN per unit gas amount of the equal PN line L7 at the water temperature T4[ ° C ].

In the present embodiment, when the warm-up operation of the engine 2 is performed and the water temperature of the engine 2 is increased, the change pattern of the operating point of the engine 2 can be divided into, for example, 3 patterns of maintaining the amount of power generation, increasing the amount of power generation, and decreasing the amount of power generation. The operating point of the engine 2 may be changed stepwise or continuously as the water temperature of the engine 2 increases.

First, a case (maintenance power generation amount) in which the power generation amount of the generator 3 is equalized when the water temperature of the engine 2 is T2[ ° c and T4[ ° c) will be described.

When the water temperature of the engine 2 rises from T2℃ to T4℃ in conjunction with the warm-up operation of the engine 2, the engine control device 20 moves the operating point P4 of the engine 2 on the equal PN line L6 at the water temperature T2℃ to the equal PN line L7 at the water temperature T4℃ along the equal power line L8. Thus, at the water temperature T2[ ° C ] and the water temperature T4[ ° C ], the engine 2 can be operated at the operating point (a) of the engine 2 where the engine output is equal to PN per unit gas amount. Therefore, PN per unit gas amount can be made the same at the water temperature T2[ ° C ] and the water temperature T4[ ° C ], and the power generation amount can be maintained.

Further, the operating point (a) of the engine 2 at the water temperature of the engine 2 of T4[ ° c ] is shifted to the engine rotation speed Ne1 (< Ne2) lower than the engine rotation speed Ne2 at the operating point P4 of the engine 2 at the water temperature of T2[ ° c ], and the NV can be reduced.

Next, a case where the amount of power generated by the generator 3 is increased (higher power generation amount) when the water temperature of the engine 2 is T4[ ° c) than when the water temperature of the engine 2 is T2[ ° c) will be described.

The engine control device 20 moves the operating point of the engine 2 to any one of a plurality of operating points (b) located within a range higher than the engine rotational speed Ne1 and lower than the engine rotational speed Ne2 of the operating point (a) on the equal PN line L7 when the water temperature of the engine 2 increases from T2[ deg.c ] to T4[ deg.c ] with the warm-up operation of the engine 2. Since the operating point (b) has a higher engine torque and a higher engine speed than the operating point (a) on the equal PN line L7, the engine output increases and the power generation amount of the generator 3 increases. Therefore, at the water temperature T4[ ° C ], PN per unit gas amount can be made the same as at the water temperature T2[ ° C ], and high power generation can be achieved as compared to at the water temperature T2[ ° C ]. Therefore, the charging time of the battery 5 can be accelerated. Further, by increasing the engine output to achieve high power generation, the engine speed is shifted to a higher speed at the water temperature T4 than at the water temperature T2 than when the power generation is maintained at the water temperatures T2℃ and T4℃, and therefore the time required for warming up the engine 2 can be shortened.

Next, a case where the amount of power generation by the generator 3 is reduced at T4[ ° c) as compared to the case where the water temperature of the engine 2 is T2[ ° c (low power generation amount) will be described.

The engine control device 20 moves the operating point of the engine 2 to any one of a plurality of operating points (c) located on the lower engine speed side than the operating point (a) on the equal PN line L7 when the water temperature of the engine 2 increases from T2℃ to T4℃ in conjunction with the warm-up operation of the engine 2. Since the operating point (c) is lower in engine torque and lower in engine speed than the operating point (a) on the equal PN line L7, the engine output decreases and the power generation amount of the generator 3 decreases. Therefore, at the water temperature T4[ ° C ], PN per unit gas amount can be made the same as at the water temperature T2[ ° C ], and quantification of low power generation can be achieved as compared to at the water temperature T2[ ° C ]. Further, by reducing the engine output to reduce the power generation, the engine speed is shifted to a lower speed than at the water temperature of T2 at the water temperature of T4 at the water temperature of T2 at c, compared to the case where the power generation is maintained at the water temperature of T2 at c and the water temperature of T4 at c, and therefore, further reduction in NV can be achieved.

Fig. 6 is a diagram showing an example of a power generation map defining a relationship between the vehicle speed and the engine speed in the first engine intermittent operation mode. Fig. 7 is a time chart showing changes in the engine speed, the water temperature of the engine 2, and the SOC of the battery 5 in the first engine intermittent operation mode. In the upper graph of fig. 7, the solid line indicates the engine speed, and the broken line indicates the vehicle speed. In the middle graph of fig. 7, the solid line indicates the water temperature of the engine 2, the broken line indicates the vehicle speed, and the alternate long and short dash line indicates the target water temperature. In the lower graph of fig. 7, the solid line indicates the SOC of the battery 5, and the broken line indicates the vehicle speed.

In the electric vehicle 1 of the embodiment, even in the CS mode in which the battery 5 can be charged with the electric power generated by the generator 3, the battery 5 is not charged with the electric power generated by the generator 3 when the SOC of the battery 5 is equal to or greater than a predetermined value. That is, in the CS mode, the intermittent operation of the engine 2 can be performed in which the operation of the engine 2 is stopped without performing the power generation of the generator 3.

On the other hand, when the warm-up of the engine 2 is not sufficiently performed, in other words, when the water temperature of the engine 2 is low, PN per unit gas amount generated at the time of starting the engine 2 becomes particularly large. Therefore, the electrically powered vehicle 1 according to the present embodiment has the first engine intermittent operation mode in which the intermittent operation of the engine 2 is prohibited when the water temperature of the engine 2 is lower than the target water temperature in the CS mode. In this first engine intermittent operation mode, for example, in fig. 6, the intermittent operation of the engine 2 is prohibited when the water temperature of the engine 2 is T1[ ° c ] or T3[ ° c ], and the intermittent operation of the engine 2 is permitted when the water temperature of the engine 2 is T5[ ° c ]. In addition, when the intermittent operation of the engine 2 is permitted, for example, when the water temperature of the engine 2 is T5[ ° c ], the operation of the engine 2 is stopped when the vehicle speed is less than the threshold V1[ km/h ], and the operation of the engine 2 is performed when the vehicle speed is equal to or more than the threshold V1[ km/h ]. In the intermittent operation of the engine 2, the relationship between the water temperature of the engine 2 and the threshold value of the vehicle speed, which is used as a criterion for determining the operation and the stop of the operation of the engine 2, may be determined in advance by an experiment or the like.

As a result of intensive studies, the inventors of the present application have found that PN per unit gas amount may be negligible when the water temperature of the engine 2 is 60[ ° c (T5 [ ° c ]) or more, for example. Therefore, in the first engine intermittent operation mode, for example, as shown in fig. 7, the target water temperature as a criterion for prohibiting and permitting the intermittent operation of the engine 2 is set to 60[ ° c ]. The engine control device 20 prohibits the intermittent operation of the engine 2 when the water temperature of the engine 2 is less than 60℃, and permits the intermittent operation of the engine 2 when the water temperature of the engine 2 is 60℃ or more.

Further, when the intermittent operation of the engine 2 is permitted, the threshold value of the vehicle speed, which is a criterion for determining the operation and the stop of the operation of the engine 2, is set to, for example, 40[ km/h ] ([ V1[ km/h ]). The engine control device 20 stops the operation of the engine 2 when the vehicle speed is less than 40[ km/h ], and operates the engine 2 when the vehicle speed is 40[ km/h ] or more. In this way, the engine control device 20 limits the engine speed according to the vehicle speed, and when the vehicle speed is less than 40[ km/h ], by stopping the operation of the engine 2, it is possible to achieve a low NV at a low vehicle speed at which the rider is relatively easily aware of noise and vibration generated along with the operation of the engine 2.

Therefore, in the electrically powered vehicle 1 of the embodiment, the engine control device 20 can simultaneously achieve reduction of PN per unit gas amount and reduction of NV by limiting the engine rotation speed according to the vehicle speed in the first engine intermittent operation mode.

Further, the engine control device 20 may perform control to reduce the engine speed as compared with the case where the vehicle speed is 40[ km/h ] or more without stopping the operation of the engine 2 when the vehicle speed is less than 40[ km/h ]. This can reduce NV in response to a decrease in the engine speed.

Further, the engine control device 20 prohibits the intermittent operation of the engine 2 when the water temperature of the engine 2 is less than 60[ ° c ], thereby continuously operating the engine 2 during the warm-up of the engine 2, and therefore, the time required for completion of the warm-up of the engine 2 can be shortened.

In the electric vehicle 1, the output of the motor generator 6 required to drive the drive wheels 8 increases as the vehicle speed increases. Therefore, in the electrically powered vehicle 1 of the embodiment, as shown in fig. 6, the engine speed increases as the vehicle speed increases, thereby increasing the engine output and increasing the power generation amount of the generator 3. At this time, the noise and vibration generated with the operation of the engine 2 increase as the engine speed increases, but at a high vehicle speed, the rider is relatively unnoticed, and therefore deterioration of NV can be suppressed.

Fig. 8 is a diagram showing an example of a power generation map defining a relationship between the vehicle speed and the engine speed in the second engine intermittent operation mode. Fig. 9 is a time chart showing changes in the engine speed, the water temperature of the engine 2, and the SOC of the battery 5 in the second engine intermittent operation mode. In the upper graph of fig. 9, the solid line indicates the engine speed, and the broken line indicates the vehicle speed. In the middle graph of fig. 9, the solid line indicates the water temperature of the engine 2, the broken line indicates the vehicle speed, and the alternate long and short dash line indicates the target water temperature. In the lower graph of fig. 9, the solid line indicates the SOC of the battery 5, and the broken line indicates the vehicle speed.

In the electric vehicle 1 of the embodiment, normally, only the motor generator 6 is driven to travel with the operation of the engine 2 stopped, and therefore, there is a possibility that the rider does not want to feel noise and vibration generated along with the operation of the engine 2. The rider is likely to notice noise and vibration generated by the operation of the engine 2 at a low vehicle speed, particularly when the electric vehicle 1 is stopped by waiting for a traffic signal or the like. Therefore, as shown in fig. 8, the electric powered vehicle 1 of the embodiment has a second engine intermittent operation mode that allows the intermittent operation of the engine 2 regardless of the warm-up state of the engine 2, in other words, regardless of the water temperature of the engine 2.

In the second engine intermittent operation mode, for example, in fig. 8, when the water temperature of the engine 2 is T1[ ° c ] and the vehicle speed is less than the threshold V2[ km/h ], the operation of the engine 2 is stopped, and when the vehicle speed is equal to or greater than the threshold V2[ km/h ], the operation of the engine 2 is performed. Further, when the water temperature of the engine 2 is T3℃ and the vehicle speed is less than the threshold V3[ km/h ], the operation of the engine 2 is stopped, and when the vehicle speed is not less than the threshold V3[ km/h ], the operation of the engine 2 is performed. Further, when the water temperature of the engine 2 is T5℃ and the vehicle speed is less than the threshold V4[ km/h ], the operation of the engine 2 is stopped, and when the vehicle speed is not less than the threshold V4[ km/h ], the operation of the engine 2 is performed. Thus, regardless of the water temperature of the engine 2, the NV can be reduced when the vehicle speed is low, in which the rider is relatively interested in noise and vibration generated by the operation of the engine 2.

Therefore, in the electrically powered vehicle 1 of the embodiment, the engine control device 20 can simultaneously achieve reduction of PN per unit gas amount and reduction of NV by limiting the engine speed in accordance with the vehicle speed in the second engine intermittent operation mode.

As shown in fig. 9, in the second engine intermittent operation mode, during the intermittent operation of the engine 2 after the water temperature of the engine 2 reaches the target water temperature (60[ ° c ]), the operation of the engine 2 is performed to compensate for a decrease in SOC of the battery 5 caused by stopping the operation of the engine 2 with the intermittent operation. For example, after the water temperature of the engine 2 reaches the target water temperature (60 [% ]), the engine control device 20 increases the engine speed to increase the engine output and increase the power generation amount of the generator 3 at predetermined timings t1 and t2 when the SOC of the battery 5 is lower than 25 [% ].

In the electric vehicle 1 of the embodiment, the switching between the first engine intermittent operation mode and the second engine intermittent operation mode is performed, for example, as follows: the rider operates a mode changeover switch, not shown, provided in the vehicle interior, and the engine control device 20 performs changeover based on a signal from the mode changeover switch. The switching between the first engine intermittent operation mode and the second engine intermittent operation mode is not limited to the mode in which the occupant operates the mode switching switch. For example, it is also possible to proceed as follows: the rider issues words for identifying the first engine intermittent operation mode and the second engine intermittent operation mode to a sound collection unit of a sound recognition device provided in the vehicle, and the engine control device 20 switches between the first engine intermittent operation mode and the second engine intermittent operation mode based on a signal from the sound recognition device corresponding to the words. Alternatively, the driver may be photographed by a camera provided in the vehicle, the driver may be specified by an image recognition device based on the photographed image, and the mode may be switched by the engine control device 20 so that the engine intermittent operation mode is set to one of the first engine intermittent operation mode and the second engine intermittent operation mode registered in advance for the specified driver.

Fig. 10 is a flowchart showing an example of control for selecting the power generation map according to the warm-up state of the engine 2.

First, the engine control device 20 determines whether or not the CS mode is established (step S1). If the mode is not the CS mode (no in step S1), the engine control device 20 ends the series of control. On the other hand, in the case of the CS mode (YES in step S1), the engine control device 20 acquires vehicle speed information from a vehicle speed sensor (step S2). Next, the engine control device 20 acquires the water temperature information of the engine 2 from the water temperature sensor 10 (step S3). Next, the engine control device 20 determines whether or not the water temperature Thw of the engine 2 detected by the water temperature sensor 10 is less than 60[ ° c of the target water temperature (step S4).

When it is determined that the water temperature Thw of the engine 2 is less than 60[ ° c (yes in step S4), the engine control device 20 selects, as a power generation map, a torque/rotation speed limitation map in which limitation conditions are set for the engine torque and the engine rotation speed (step S5). Next, the engine control device 20 determines operating points (Ne, Te) on the iso-PN line along the target corresponding to the water temperature of the engine 2, using the torque/rotation speed limit map (step S6). Further, "Ne" is an engine rotational speed, and "Te" is an engine torque.

Next, the engine control device 20 continuously operates the engine 2 at the operating points (Ne, Te) determined in step S6, performs power generation control in which the generator 3 generates power (step S7), and ends the series of control.

When it is determined in step S4 that the water temperature Thw of the engine 2 is not less than 60[ ° c (no in step S4), the engine control device 20 selects a reference power generation map, in which a restriction condition is set only for the engine speed, as a power generation map (step S8). Next, the engine control device 20 allows the intermittent operation of the engine 2 (step S9). Next, the engine control device 20 determines whether the vehicle speed is less than a threshold value (step S10). When it is determined that the vehicle speed is less than the threshold value (yes in step S10), the engine control device 20 stops the operation of the engine 2 (step S11) and ends the series of control.

On the other hand, when determining that the vehicle speed is not less than the threshold value (NO at step S10), the engine control device 20 proceeds to step S6.

Fig. 11 is a flowchart showing an example of control for selecting a power generation map corresponding to the warm-up state of the engine 2 and changing the operating point of the engine 2 in accordance with a change in the SOC of the battery 5.

First, the engine control device 20 determines whether or not the CS mode is established (step S21). If the mode is not the CS mode (no in step S21), the engine control device 20 ends the series of control. On the other hand, in the case of the CS mode (YES in step S21), the engine control device 20 acquires vehicle speed information from a vehicle speed sensor (step S22). Next, the engine control device 20 acquires the water temperature information of the engine 2 from the water temperature sensor 10 (step S23). Next, the engine control device 20 determines whether or not the water temperature Thw of the engine 2 detected by the water temperature sensor 10 is less than 60[ ° c of the target water temperature (step S24).

When it is determined that the water temperature Thw of the engine 2 is less than 60[ ° c (yes in step S24), the engine control device 20 selects the torque/rotation speed limit map as the power generation map (step S25). On the other hand, if it is determined that the water temperature Thw of the engine 2 is not less than 60[ ° c (no in step S24), the engine control device 20 selects the reference power generation map as the power generation map (step S26).

Next, after the torque/rotation speed limit map is selected in step S25 or after the reference power generation map is selected in step S26, the engine control device 20 calculates the transition of the SOC of the battery 5 (step S27). Next, the engine control device 20 determines whether or not the SOC of the battery 5 has changed by 1% or more per 2 km, which is a running distance (step S28).

When determining that the SOC of the battery 5 has changed by 1% or more per 2 km of the running distance (yes in step S28), the engine control device 20 determines whether the SOC of the battery 5 has decreased (step S29).

When determining that the SOC of the battery 5 has decreased (YES in step S29), the engine control device 20 selects an operating point of the engine 2, which is an operating point at which the power generation amount of the generator 3 is increased by 1[ kW ] from the reference power generation amount (step S30). Then, the engine control device 20 determines the operating points (Ne ', Te') corresponding to the water temperature of the engine 2 so that the amount of power generation increases by 1[ kW ] with respect to the reference amount of power generation (step S31). Next, the engine control device 20 operates the engine 2 at the determined operating points (Ne ', Te'), performs power generation control for generating power by the power generator 3 (step S36), and ends the series of control.

If it is determined in step S29 that the SOC of the battery 5 is not reduced (no in step S29), the engine control device 20 selects an operating point at which the power generation amount of the generator 3 is reduced by 0.5 kW with respect to the reference power generation amount (step S32). Then, the engine control device 20 determines the operating point (Ne ″, Te ″) corresponding to the water temperature of the engine 2 so that the amount of power generation is reduced by 0.5 kW from the reference amount of power generation (step S33). Next, the engine control device 20 operates the engine 2 at the determined operating point (Ne ", Te"), performs power generation control for generating power by the generator 3 (step S36), and ends the series of control.

If it is determined in step S28 that the SOC of the battery 5 has not changed by 1% or more per 2 km of the running distance (no in step S28), the engine control device 20 maintains the reference power generation amount (step S34). The reference power generation amount is, for example, 5 to 7 kW. Then, the engine control device 20 determines the operating points (Ne, Te) corresponding to the water temperature of the engine 2 so as to maintain the reference power generation amount (step S35). Next, the engine control device 20 operates the engine 2 at the determined operating points (Ne, Te), performs power generation control for generating power by the generator 3 (step S36), and ends the series of control.

Description of the reference numerals

1 electric vehicle

2 engines

3 electric generator

4 PCU (Power control Unit)

5 Battery

6 electric generator

7 differential gear

8 driving wheel

9 plug

10 water temperature sensor

20 engine control device