JP3675383B2 - Electric vehicle regenerative braking control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an electric vehicle that travels by driving wheels by an electric motor, and more particularly to an electric vehicle regenerative braking control device that controls regenerative braking by an electric motor according to road conditions and driver characteristics.
[0002]
[Prior art]
  In recent years, an electric vehicle (electric vehicle) has been attracting attention from the viewpoint of preventing air pollution and reducing noise caused by the vehicle. In such an electric vehicle, so-called regenerative braking can be easily performed. This regenerative braking can be performed by switching a driving electric motor (hereinafter referred to as a motor) to a power generation operation, and recovers rotational energy of driving wheels as electric energy via the motor.
[0003]
  Such regenerative braking is generally controlled so that braking force is generated in conjunction with depression of the brake pedal or release of the accelerator pedal.
  By the way, when the accelerator pedal is not depressed and the brake pedal is not depressed, regenerative braking is weaker than when the brake pedal is depressed so that it corresponds to engine braking in the case of an automobile driven by an internal combustion engine. (This regeneration is referred to as weak regeneration). If excessive regenerative braking force is generated at this time, the vehicle speed may drop more than the driver requires.
[0004]
  In addition, when regenerative braking is generated in low vehicle speed traveling such as urban traveling, the excitation power supplied to the motor becomes larger and energy saving is not achieved.
  Therefore, for example, Japanese Patent Application Laid-Open No. 5-122805 proposes a technique that allows a weak regenerative braking force corresponding to an engine brake that works when an accelerator pedal or a brake pedal is returned in an electric vehicle to be changed manually. Yes.
[0005]
[Problems to be solved by the invention]
  However, in the above-described prior art disclosed in Japanese Patent Laid-Open No. 5-122805, the regenerative braking force is adjusted by manual operation. Therefore, it may be necessary to frequently change the weak regeneration depending on the gradient change when traveling on a slope. It will be a burden.
  The present invention has been devised in view of the above-described problems, and an appropriate regenerative braking force can be obtained according to the road conditions on which the vehicle travels, the characteristics of the driver, etc. without requiring frequent manual operation. An object of the present invention is to provide a regenerative braking control device for an electric vehicle.
[0006]
[Means for Solving the Problems]
  For this reason, the regenerative braking control device for an electric vehicle according to the first aspect of the present invention includes an electrical energy supply source mounted on the vehicle, an electrical connection to the electrical energy supply source, and an output shaft connected to the electrical energy supply source. An electric motor coupled to a drive wheel of a vehicle, and a gradient detection means for detecting a gradient state during traveling of the vehicleAnd brake frequency detecting means for detecting the brake frequency of the driverAnd a control means for controlling the regenerative braking force of the electric motor based on detection information from the gradient detection means in the driving state detection means, the control means detecting the driving state Road condition determining means for determining the traveling road condition of the vehicle based on the detection result of the meansDriving characteristic determining means for determining the driving characteristic of the driver based on detection information from the brake frequency detecting means;The control means includes a detection result from the slope detection means and determination information from the road condition determination means.Determination information of the driving characteristic determination means andOn the basis of the above, the regenerative braking force by the electric motor is controlled.
[0007]
  According to a second aspect of the present invention, there is provided the regenerative braking control device for an electric vehicle according to the first aspect, wherein the driving state detecting means detects the vehicle speed of the vehicle, and the steering angle of the vehicle. And a road condition determination unit that detects the vehicle road based on the vehicle speed detected by the vehicle speed detection unit and the steering angle detected by the steering angle detection unit. It is characterized by determining the type of.
[0008]
  According to a third aspect of the present invention, there is provided an electric vehicle regenerative braking control device according to the present invention, wherein the electric energy supply source mounted on the vehicle is electrically connected to the electric energy supply source, and the output shaft is connected to the vehicle. Motor connected to the driving wheel of the vehicle, and a gradient detecting means for detecting a gradient state during traveling of the vehicleAnd brake frequency detecting means for detecting the brake frequency of the driverAnd a control means for controlling the regenerative braking force of the electric motor based on detection information from the gradient detection means in the driving state detection means, the control means detecting the driving state Driving characteristic determination means for determining the driving characteristic of the driver of the vehicle based on the detection result of the means, and the control means is based on the detection result from the gradient detection means and the determination information of the driving characteristic determination means. The regenerative braking force by the electric motor is controlled.
[0009]
  The regenerative braking control device for an electric vehicle according to a fourth aspect of the present invention is the regenerative braking control device for an electric vehicle according to the third aspect, wherein the driving state detecting means includes an accelerator opening detecting means for detecting an accelerator opening of the vehicle, Brake operation detection means for detecting the operation state of the brake of the vehicle,The brake frequency detection means detects the brake frequency based on detection information from the brake operation detection means;The driving characteristic determining means includes the accelerator opening detected by the accelerator opening detecting means, and the brakefrequencyThe brake detected by the detection meansOperation frequencyThe driving characteristics are determined based on the above.
[0010]
  Claims5The regenerative braking control device for an electric vehicle according to the present invention is described above.4In any one of the above, the control means includes storage means for determining the regenerative braking force by the electric motor in accordance with the detection result of the gradient detection means, and the regenerative braking force corresponding to the detection result is obtained. The regenerative braking force by the electric motor is controlled so that the regenerative braking force is read out from the storage means.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, an embodiment of a regenerative braking control device for an electric vehicle according to the present invention will be described with reference to the drawings.The
  ThisThe fruitIn the regenerative braking control device for an electric vehicle according to the embodiment, as shown in FIG. 1, reference numeral 1 denotes a battery as an electric energy supply source, and this battery 1 can be repeatedly charged by an external charger not provided in the vehicle. . Reference numeral 2 denotes an electric motor (traveling motor) to which electric power is supplied from the battery 1, and driving wheels 4 are drivingly connected to an output shaft of the motor 2 via a transmission 3. A power conversion circuit 5 is provided between the battery 1 and the motor 2. The power from the battery 1 is adjusted to a required size through the power conversion circuit 5 and supplied to the motor 2. Yes.
[0012]
  The power conversion circuit 5 is controlled through a motor controller 6. The motor controller 6 controls the output of the motor 2 through the power conversion circuit 5 in accordance with the amount of depression of an accelerator pedal (not shown). And in the motor controller 6, the regeneration control part (control means) 7 is provided.
[0013]
  The regenerative control unit 7 controls the state of the regenerative braking. As is well known, the regenerative braking itself recovers the kinetic energy of the drive wheels 4 by switching the driving motor 2 to the power generation operation. This is braking for charging the battery 1 as electric energy.
  In order to control such regenerative braking, the regenerative control unit 7 includes a storage unit 8, a determination unit 9, a calculation unit 10, an instruction unit 11,Road condition determining means 31, driving characteristic determining means 32,Is provided.
[0014]
  The regenerative control unit 7 includes an operating state detecting means 20, that is, a brake opening detecting means (may be a brake switch) 21 as a brake operation detecting means, and an accelerator opening detecting means (accelerator switch). 22), motor torque detection means 23, vehicle speed detection means (vehicle speed sensor) 24, steering angle detection means (steering angle sensor) 25, motor rotation speed detection means (rotation speed detection means) 26, shift position detection means (forward). -Reverse detection means) 27, gradient detection means 28, Regeneration amount adjustment switch 29 and brake frequency detection means 30Is connected, brake operation information, accelerator operation information, motor torque information, vehicle speed information, steering angle information, motor rotation speed information, vehicle forward / backward information and road gradient information, regeneration amount adjustment information, Brake frequencyThe information concerning the operation state and the operation state such as is input. The regenerative amount adjustment switch 29 is a manual operation member that can adjust the strength of regenerative braking by a driver's manual operation.
[0015]
  The storage means 8 described above includes, for example, vehicle specification data such as vehicle weights W and W0, vehicle front projection area S, rolling resistance coefficient μr, air resistance coefficient μc, transmission gear ratio nt, and final reduction gear ratio nf. In addition, a gradient-regeneration increase / decrease table (or map) and a rotation speed-regeneration table (or map) described later, a table (or map) related to the turning resistance Rc, and the like are stored.
[0016]
  The determination unit 9 determines whether or not regenerative braking is performed based on various information from the driving state detection unit 20. For example, the shift position detection unit 27 determines whether the vehicle is in a forward state or a reverse state. From the shift position information from Further, the calculation means 10 performs a calculation for controlling the regenerative braking force. The calculation means 10 is provided with a regenerative braking force calculation means (or calculation means) 12.
[0017]
  The regenerative braking force calculation means 12Reference gain setting means 12A, increase / decrease gain setting means 12B, road driving condition coefficient setting means 12C, and regeneration command value calculation means 12D are provided. Here, the regenerative braking force calculating means 12 will be described. The reference gain setting means 12A is a means for setting a reference gain based on detection information from the brake opening degree detecting means 21 and the rotation detecting means 26, and an increase / decrease gain. The setting means 12B is a means for setting an increase / decrease gain according to the gradient state during travel of the vehicle, and the road driving condition coefficient setting means 12C is a means for setting the road driving condition coefficient according to the road condition and driving characteristics. Yes, the regenerative command value calculation means 12D is based on the reference gain, increase / decrease gain, and road driving state coefficient set by each of the setting means 12A, 12B, 12C, and the regenerative command value (regenerative control that gives a required regenerative braking force). (Quantity) is a means for calculating.
[0018]
  That is, in this regenerative braking force calculation means 12, a regenerative gain equivalent to engine braking is obtained as shown in the following equation.(Weak regeneration gain)Set.
  Engine brake equivalent regeneration gain =(Reference gain + increase / decrease gain) x road driving condition coefficient                                                          ・ ・ ・ ・ ・ ・ （1.0）
  this house,Set by reference gain setting means 12AFor example, when performing weak regeneration when the brake is not operated, the reference gain is set to be proportional to the rotation speed (rotational speed) of the motor 2 as shown in FIG. That is, the rotation speed-regeneration table or map having the characteristics as shown in FIG. 2 is stored in the storage means 8, and the reference gain is calculated from the rotation speed of the motor 2 based on this table or map.
[0019]
  Also,Set by increase / decrease gain setting means 12BThe increase / decrease gain is set according to the grade of the road (gradient resistance) as shown in FIG. 3 or FIG. The setting characteristics shown in FIG. 3 can be applied to all vehicles equipped with ABS (anti-lock brake system), and can be applied to vehicles that are not equipped with ABS, in which the drive wheels are positioned forward in the traveling direction. That is, the present invention can be applied when the front wheel drive vehicle is moving forward and when the rear wheel drive vehicle is moving backward.
[0020]
  On the other hand, the setting characteristics shown in FIG. 4 can be applied to the case where the driving wheel is located rearward in the traveling direction in the case of an automobile not equipped with ABS. That is, the present invention can be applied when the front wheel drive vehicle is moving backward and when the rear wheel drive vehicle is moving forward. In the case shown in FIG. 3, the increase / decrease gain is on the decrease side (that is, the decrease gain) at the upslope (the slope resistance is positive), and the magnitude of the decrease gain is increased according to the magnitude of the upslope. Will increase. On the other hand, when the slope is negative (the slope resistance is negative), the increase / decrease gain is increased (that is, increased gain), and when the degree of the downward slope is increased, the magnitude of the increase gain increases according to the magnitude.
[0021]
  However, a dead zone is provided in a region range where the gradient resistance is near 0 (that is, in the case of a flat road and a gradient state close to a flat road), so that control is stabilized. Further, a minimum limit and a maximum limit of increase / decrease gain are provided, and when the degree of the upward gradient becomes stronger than a predetermined value, the minimum limit, that is, the magnitude of the decrease gain becomes the maximum value (= −100%), and the downward gradient When the degree of is higher than a predetermined value, the maximum limit, that is, the magnitude of the increase gain is set to the maximum value (= 100%), and feasible control is performed.
[0022]
  In the case shown in FIG. 4, as shown by the solid line, the increase / decrease gain is on the decrease side (that is, the decrease gain) when the gradient is positive (the gradient resistance is positive), and decreases according to the magnitude of the gradient when the gradient of the gradient increases The magnitude of the gain increases. However, on a downward slope (gradient resistance is negative), the increase / decrease gain is held at 0%, which is the same as on a flat road. As described above, the reason why the increase / decrease gain is set to 0% and the correction is not performed on the downward slope is as follows.
[0023]
  That is, although the regenerative braking force is applied to the drive wheels, as shown in FIG. 5, when the front wheel drive vehicle is moving downhill or the rear wheel drive vehicle is moving downhill, Is located above the gradient road, the regenerative braking force is applied to the wheels above the gradient road. Since the wheel above such a slope road has little vehicle weight sharing, there is a possibility that the wheel will be locked if the regenerative braking force is increased. Therefore, when the driving wheel to which the regenerative braking force is applied is positioned above the gradient road, the increase / decrease gain is set to 0% and the increase correction is not performed.
[0024]
  In a vehicle with an ABS, since the ABS itself prevents the wheels from being locked, such an increase / decrease gain 0 is not necessary, and the increase / decrease gain is set as shown in FIG. Also for such an increase / decrease gain, a gradient-increase / decrease regeneration table or map having characteristics as shown in FIGS. 3 and 4 is stored in the storage unit 8, and the increase / decrease gain is calculated from the gradient state based on this table or map. It is like that. Further, the increase / decrease gain for the gradient resistance may be set using broken line interpolation based on four or more specific points (broken points or the like) in FIGS.
[0025]
  Next, the road driving condition coefficient set by the road driving condition coefficient setting means 12C will be described. As shown in FIGS. 1 and 6, the road driving condition coefficient setting means 12C is provided in the driving condition detection means 20. Road set based on each driving state data from motor torque detecting means 23, vehicle speed detecting means (vehicle speed sensor) 24, steering angle detecting means (steering angle sensor) 25, motor rotation speed detecting means (rotation detecting means) 26 A road driving state coefficient as shown in FIG. 7 is set in accordance with the degree of the situation and driving characteristics.
[0026]
That is, the road situation is any of the types of roads, that is, urban areas, highways, mountainous roads, and congested roads based on the vehicle speed, motor torque, motor rotation speed, and steering angle in the road situation determination means 31 described later. The driving characteristic is determined by driving characteristic determination means 32 described later as to whether the driving characteristic of the driver is loose, crisp, or intermediate (normal).
[0027]
In contrast to the road conditions and driving characteristics determined in this way, as shown in FIG. 7, when the driving characteristics are loose, the road driving condition coefficient is set slightly smaller so that the regeneration degree tends to be weakened. If the driving characteristics are sharp, the coefficient is set to be slightly larger to increase the regenerative degree. Also, on the highway, the coefficient Set a small value to weaken the regenerative degree, set the regenerative degree to an intermediate state without changing the coefficient on congested roads, set the coefficient slightly larger in urban areas, and tend to slightly increase the regenerative degree. The coefficient is set to a large value to increase the regeneration level.
[0028]
Here, the road condition determining means 31 and the driving characteristic determining means 32 will be described in detail. In the road condition determining means (road traffic condition estimating means) 31 described above, as shown in FIG. Based on the steering angle, the traveling road situation determination (road traffic situation estimation) is performed, and this traveling road situation determination is specifically performed as shown in FIG.
[0029]
That is, vehicle speed V B Further, for example, a running time ratio, an average speed, and an average lateral acceleration are obtained from the steering angle (steering angle) δ as parameters of the vehicle running state. At this time, each of these parameters may be obtained based on the detected value obtained by detecting the motor torque and the motor rotational speed together with the vehicle speed, or based on the vehicle speed, the motor torque, and the motor rotational speed.
[0030]
Among these, the average speed and the average lateral acceleration are general values and are calculated by a known method. On the other hand, the travel time ratio is the travel time Td and stop time T of the vehicle. s And the total time T all The ratio of the travel time Td to (= Td + Ts) [= Td / (Td + Ts)], and the vehicle speed V when the ignition is on. B Is equal to or less than a predetermined value (for example, 10 km / h), the stop time Ts is counted and the vehicle speed V B Is greater than a predetermined value (for example, 10 km / h), the traveling time Ts is counted and calculated.
[0031]
Based on these travel time ratios, average speeds, and average lateral accelerations, the urban area degree, the high speed road degree, the mountain road degree, and the congestion road degree are estimated. Here, fuzzy reasoning is used for these estimations. For example, in the case of urban areas, the average speed is low and the running time ratio is medium, and in the case of a highway, the average speed is high, the driving time ratio is high, and the integral value of the lateral acceleration is low. In this case, the travel time ratio is high and the integral value of the lateral acceleration is high. In a congested road, the average speed is low and the travel time ratio is low. By setting the membership function and the fuzzy rule based on such characteristics, it is possible to estimate the urban area degree, the highway degree degree, the mountainous degree degree, and the traffic jam degree.
[0032]
Then, the road condition determination means 31 determines the road condition at the highest frequency from among the urban area degree, the highway degree degree, the mountainous degree degree, and the traffic jam degree.
Further, as shown in FIGS. 1 and 6, the above-mentioned driving characteristic determination means 32 detects the road condition determined by the road condition determination means 31 and the accelerator position and brake frequency detected by the accelerator position detection means 22. Based on the brake frequency detected by the means 30, the driving characteristics of the driver are determined. The brake frequency detection means 30 can determine the brake frequency by dividing the number of brake operations or / and the brake operation time based on the brake opening degree detection means 21 or the brake switch by the travel time.
[0033]
Here, the driving characteristics of the driver are defined as follows. In other words, the driver prefers to travel at a relatively constant speed with slow acceleration and deceleration (such a travel is referred to as “slow travel”), or the driver accelerates and decelerates quickly and relatively quickly at high speed. The driver's driving characteristics are the degree of comfortable driving and the degree of frequent driving such as whether such driving is referred to as “quick running”. Such driving characteristics can be estimated based on a physical quantity representing the driving state of the vehicle.
[0034]
However, since the driving characteristic of the driver changes according to the road traffic situation in which the vehicle travels, the driving characteristic determination unit 32 takes into consideration the road condition determined by the road condition determination unit 31 as described above. The driving characteristics of the driver represent this road condition and the driving condition of the above vehicle Determination is made as shown in FIG. 9 based on physical quantities (that is, the accelerator opening, the vehicle speed, the longitudinal acceleration that can be calculated from the vehicle speed, and the lateral acceleration that can be calculated from the vehicle speed and the steering angle (handle angle)). .
[0035]
That is, first, frequency analysis is performed on each physical quantity (accelerator opening, vehicle speed, longitudinal acceleration, lateral acceleration) representing the driving state of the vehicle by a known statistical method, and an average value and variance of each physical quantity are calculated.
Then, based on the average value and variance of each physical quantity, and the estimated urban area degree, traffic jam degree degree, and mountain road degree road traffic situation, the average value of each physical quantity characterized for each road situation and The driving characteristics of the driver can be estimated from the correspondence between the variance and the driving characteristics of the driver.
[0036]
Here, a neural network is used to estimate the driving characteristics. In other words, the average value and variance of each physical quantity increase as the driver's driving becomes more strict, and the average value and variance of each physical quantity become lower as the driver's driving becomes more relaxed. Of course, this is evaluated on a different scale for each road condition, but the neural network is designed so that the correspondence between the average value and variance of each physical quantity according to each road condition and the driving characteristics of the driver is an associative model. Forming.
[0037]
Then, the average value and variance of each physical quantity, and the road traffic situation of urban degree, congestion degree, and mountainous degree are input to this neural network so as to obtain the driving characteristics of the driver (relaxation degree or severity). Yes.
Of course, the driving characteristics are estimated while always inputting the latest data as physical quantities and road conditions, and can be estimated according to changes in the driving characteristics of the driver. It is like that. Therefore, the looseness or the crispness obtained by the driving characteristic estimation means is a value obtained by appropriately estimating the characteristics of the driver actually driving.
[0038]
The driving characteristic determination means 32 determines the driving characteristic of the driver in one of three stages: relaxed, normal, and acne.
When the determination is made by the road condition determining means 31 and the driving characteristic determining means 32 in this way, the road driving condition coefficient setting means 12C determines the road condition from the table as shown in FIG. 7 based on the determination result. And a road driving condition coefficient for driving characteristics can be set.
[0039]
Then, the regenerative command value calculation means 12D of the regenerative braking force calculation means 12 adds the reference gain and the increase / decrease gain set from the motor rotational speed and the gradient resistance, as shown in the equation (1.0), thereby obtaining the regenerative gain. Further, the regenerative gain is multiplied by a road driving state coefficient corresponding to road conditions and driving characteristics to obtain a final target regenerative gain, that is, a target regenerative braking force (regenerative command value). Yes.
[0040]
When the regeneration amount adjustment switch 29 is provided, the final target regeneration gain [target is obtained by multiplying the preset regeneration gain set by this switch by the target regeneration gain obtained by the above formula (1.0). The regenerative braking force or the regenerative command value] is obtained.
  Further, the regenerative braking force (regenerative amount) calculated by the regenerative braking force calculating means 12 of the computing means 8 in this way is obtained by using the primary low-pass filter 15 as means for suppressing a sudden change in the regenerative braking force setting value. Via the instruction means 11. That is, the primary low-pass filter 15 prevents a sudden change in the regenerative braking force (regenerative amount), and regenerative control can be performed without a sense of incongruity.
[0041]
  Here, the gradient detection will be described. In the gradient detecting means 28 of the present embodiment, the gradient is estimated by calculation based on the balance of forces related to the traveling of the vehicle. That is, when the vehicle is traveling, the following force balance equation is established.
  F = Ra + R ... (1.1)
  F: Tire driving force or tire braking force transmitted by the tire
        Ra: Acceleration resistance
        R: Running resistance
  Of these, the tire driving force or the tire braking force F can be calculated based on the motor torque (which can be calculated from the current command value) as in the following equation.
[0042]
  Tire driving force F = Tm x gear ratio x gear efficiency ÷ tire dynamic radius
  Tire braking force F = Tm ′ × gear ratio × gear efficiency / tire dynamic radius + Br (1.2)
  Tm: Motor power running torque (calculated from current command value)
        Tm ': Motor regeneration torque (calculated from current command value)
        Br: Mechanical brake amount
  The running resistance R is represented by R (θ, V) as a function of the road surface inclination angle θ and the vehicle speed V. The running resistance R (θ, V) is represented by the following equation.
[0043]
  R (θ, V) = W (μr · cos θ · sin θ) + μc · S · V² + Rc (1.3)
  Where W: gross vehicle weight
        S: Vehicle front projection area
        μr: Rolling resistance coefficient
        μc: Air resistance coefficient
        Rc: Turning resistance
  Note that the turning resistance Rc is obtained based on the steering angle (steering wheel angle) detected by the steering angle sensor 25 by using the table as a table of values corresponding to the steering angle based on actual vehicle data. Can do.
[0044]
  The acceleration resistance Ra can be calculated based on the vehicle acceleration a as in the following equation.
    Ra = (W + ΔW) · a / g
    ΔW = W0 {Ec + Fc (nt · nf)²}
    Ec = g · Iw / (r²* W0), Fc = g * Im / (r²・ W0) (1.4)
  However, W0: Empty weight
        a: Vehicle acceleration
        g: Gravitational acceleration [= 9.8 (m / s²)]
        nt: Transmission gear ratio
        nf: Final reduction gear ratio
        r: tire moving radius
        Iw: Tire rotation partial moment of inertia
        Im: Motor rotating partial moment of inertia
  The tire rotating portion corresponds to a tire, a brake drum, an axle shaft, and the like, and the motor rotating portion corresponds to a motor rotor, a flywheel, a clutch, and the like.
[0045]
  Moreover, the vehicle acceleration a can be calculated | required by following Formula.
  a = Δ [(motor rotational speed ÷ gear ratio) × 2π · tire radius] / Δt (1.5)
  The unit of motor rotation speed is [rotation / second], the unit of tire radius is [meter], and the unit of Δt is [second].
[0046]
  Further, the motor rotation speed is expressed as follows in units of [rpm], that is, the motor rotation speed which is the rotation speed per minute.
  Motor rotation speed = motor rotation speed ÷ 60
  Here, when formula (1.1) is substituted into formula (1.1) and rearranged,
W · sin θ≈F−Ra−W · μr−μc · S · V²-Rc (1.6)
  From such a relational expression, the gradient resistance W · sin θ or the gradient degree θ is obtained from the motor torques Tm and Tm ′ obtained from the current command value to the motor 2 and the vehicle acceleration a obtained from the detection value of the motor rotational speed sensor 26 and the like. It can be calculated from the turning resistance Rc that can be determined based on the steering angle detected by the steering angle sensor 25.
[0047]
  As described above, the regenerative braking control device for an electric vehicle according to the present embodiment is, for example, a front-wheel drive vehicle that is not equipped with ABS.10As shown in the flowchart, the regenerative braking force or the regenerative amount in the regenerative control is determined at a predetermined cycle.
That is, in step S210, it is determined whether or not the accelerator pedal is off. If the accelerator pedal is on, regenerative braking is not performed. If the accelerator pedal is off, whether or not the brake pedal is off is determined in step S220. If the brake pedal is on, a regeneration command value is set according to the brake pedal operation amount (brake opening degree) (step S2120). If the brake pedal is off, the process proceeds to step S230 and subsequent steps, and weak regenerative braking equivalent to engine braking is controlled.
[0048]
That is, first, the motor rotational speed is detected in step S230, the process proceeds to step S240, and the reference gain setting means 12A sets the reference gain based on the motor rotational speed (see FIG. 2). In step S250, the gradient detecting unit 28 detects the gradient as described above, and the process proceeds to step S260, where the increase / decrease gain setting unit 12B sets the increase / decrease gain based on this gradient (see FIGS. 3 and 4). .
[0049]
Further, the road condition determining means 31 determines the road condition (step S270), the driving characteristic determining means 32 determines the driving characteristic (step S280), and the process proceeds to step S290. The road driving condition coefficient setting means 12C A road driving state coefficient is set based on the determination result (see FIG. 7).
In step S2100, the regenerative command value calculation means 12D calculates the regenerative gain by adding the reference gain and the increase / decrease gain set from the motor rotational speed and the gradient resistance, as shown in the above formula (1.0). Further, the regenerative gain is multiplied by a road driving state coefficient corresponding to road conditions and driving characteristics to obtain a final target regenerative gain, and a target regenerative braking force (regenerative command value) is set.
[0050]
Thereafter, a regeneration command is issued in step S2110, and actual regeneration control is executed.
When the regeneration amount adjustment switch 29 is provided, the final target regeneration gain is obtained by multiplying the target regeneration gain obtained by the above formula (1.0) by the preset gain set by this switch.
[0051]
Then, the regeneration command is issued according to the regeneration command value set in step S2100 or S2120 in this way.
As a result, as shown in FIG. 11, the regenerative braking force corresponds to the degree of demand for road conditions, driver preference, and driving characteristics in addition to the degree of demand for road gradient.
[0052]
For example, although the speed is low and the acceleration change is large in an urban area, a regenerative braking force is strengthened for a driver who performs a crisp operation, so that a large acceleration change can be dealt with.
On highways, the speed is high and the change in acceleration is small. However, the regenerative braking force is greatly reduced for drivers who drive slowly, and for drivers who normally drive. Since the rate at which the regenerative braking force is weakened is small, smooth regenerative braking adapted to small acceleration changes is performed.
[0053]
On mountain roads, the speed is slightly higher and the acceleration change is extremely large. Thus, it is possible to cope with a large acceleration change according to the characteristics of the driver.
Further, on a congested road, since the average speed is low and the traveling time ratio is low, smooth regenerative braking is performed with a standard regenerative braking force.
[0054]
Of course, such control of the regenerative braking force according to the road conditions and driving characteristics is performed in consideration of the gradient state, so that appropriate regenerative control reflecting the road conditions and driving characteristics according to the gradient state is performed. Regenerative braking by power is realized.
Since the increase / decrease gain is calculated based on the characteristics as shown in FIG. 4, the magnitude of the decrease gain increases according to the magnitude of the upward gradient when the degree of the upward gradient increases. On the uphill, the greater the gradient, the more easily the vehicle decelerates due to gravity, so the need for regenerative braking force decreases accordingly.However, if the increase in regenerative gain decreases as the uphill increases, excessive regenerative braking force Is avoided, and it is possible to travel uphill smoothly and without a sense of incongruity.
[0055]
In the case of a downward slope, the increase / decrease gain is set to 0, and the regenerative braking force is maintained in the same state as that on a flat road, so that the driving wheel (regenerative braking wheel) is moved over the slope road. Even in the case where there is a risk of locking due to an increase in braking force with little burden sharing, there is an advantage that an increase in regenerative braking force is avoided and wheel locking is not invited, and the running stability of the vehicle can be maintained.
[0056]
Further, since the increase / decrease gain is set to 0 in a gentle gradient region near the flat road, there is an advantage that a regenerative braking force that is stable and has no sense of incongruity can be obtained.
When the increase / decrease gain is calculated based on the characteristics shown in FIG. 3, the magnitude of the decrease gain increases in accordance with the magnitude of the upward gradient as described above. On the uphill, the greater the gradient, the more easily the vehicle decelerates due to gravity, so the need for regenerative braking force decreases accordingly.However, if the increase in regenerative gain decreases as the uphill increases, excessive regenerative braking force Is avoided, and it is possible to travel uphill smoothly and without a sense of incongruity.
[0057]
Further, when the degree of the downward gradient becomes strong, the magnitude of the increase gain increases according to the magnitude. In descending slopes, the greater the slope, the easier the vehicle will accelerate due to gravity, so the need for regenerative braking force increases.However, the greater the descending slope, the greater the increase in regenerative gain. The braking force will be increased, and it will be possible to drive downhill smoothly and without a sense of incongruity.
[0058]
Of course, since the increase / decrease gain is set to 0 in a gentle gradient area in the vicinity of the flat road, there is also an advantage that a regenerative braking force can be obtained stably and without a sense of incongruity.
Further, by controlling the regenerative gain, it is possible to reduce the operation frequency of the accelerator and the brake, improve the regenerative efficiency, and increase the travel distance of the electric vehicle at one time.
[0059]
The output from the regenerative braking force calculating means 12 is processed by the primary low-pass filter 15, so that sudden change of the regenerative braking force (regenerative amount) is prevented and regenerative control can be performed without a sense of incongruity.
[0060]
【The invention's effect】
  As described above in detail, according to the regenerative braking control device for an electric vehicle of the present invention, the regenerative braking force according to the gradient state can be automatically generated, and it is not necessary to perform a special operation. A regenerative braking force can be obtained.
  Further, an appropriate regenerative braking force can be obtained depending on the driving characteristics and road conditions of the driver, and there is an advantage that the drivability of the electric vehicle can be improved.
[Brief description of the drawings]
FIG. 1 shows the present invention.The fruitIt is a functional block diagram which paid its attention to the principal part function in the regenerative braking control apparatus of the electric vehicle as embodiment.
FIG. 2The fruitIt is a figure which shows the characteristic of the reference | standard gain for the setting of the basic regenerative braking force by the regenerative braking control apparatus of the electric vehicle as embodiment.
FIG. 3The fruitIt is a figure which shows the characteristic of the increase / decrease gain for correction | amendment of the basic regenerative braking force by the regenerative braking control apparatus of the electric vehicle as embodiment.
FIG. 4 The present inventionThe fruitIt is a figure which shows the characteristic of the increase / decrease gain for correction | amendment of the basic regenerative braking force by the regenerative braking control apparatus of the electric vehicle as embodiment.
FIG. 5 shows the present invention.The fruitIt is a figure which shows description of the characteristic of the increase / decrease gain for correction | amendment of the basic regenerative braking force by the regenerative braking control apparatus of the electric vehicle as embodiment.
FIG. 6 shows the present invention.The fruitRegenerative braking control device for electric vehicle as embodimentIt is a block diagram which shows the principal part structure for the gradient correction | amendment by a road and the correction | amendment corresponding to a road driving state.
FIG. 7The fruitElectric vehicle regenerative braking control device as an embodimentShowing the content of road driving state gain for correction of road driving state correspondence byIt is.
FIG. 8The fruitElectric vehicle regenerative braking control device as an embodimentIt is a block diagram which shows the road condition determination means for the driving | running | working driving | operation state corresponding | compatible correction | amendment by.
FIG. 9The fruitBy regenerative braking control device for electric vehicle as embodimentIt is a block diagram which shows the driving | operation characteristic determination means for driving | running | working driving | operation state corresponding | compatible correction | amendment.
FIG. 10 shows the present invention.The fruitBy regenerative braking control device for electric vehicle as embodimentIt is a flowchart which shows the operation | movement of regenerative control.
FIG. 11 shows the present invention.The fruitRegenerative braking control device for electric vehicle as embodimentIt is a figure explaining operation | movement of.
[Explanation of symbols]
  1 Battery (electric energy supply source)
  2 Electric motor (travel motor)
  3 Transmission
  4 Drive wheels
  5 Power conversion circuit
  6 Motor controller
  7 Regenerative control unit (control means)
  8 storage means
  9 Judgment means
  10 Calculation means
  11 Instruction means
  12 Regenerative braking force calculation means
  12A Reference gain setting means
  12B Increase / decrease gain setting means
  12C road driving condition coefficient setting means
  12D regeneration command value calculation means
  15 Primary low-pass filter
  20 Operating state detection means
  21 Brake opening detection means
  22 Accelerator opening detection means
  23 Motor torque detection means
  24 Vehicle speed detection means (vehicle speed sensor)
  25 Steering angle detection means (steering angle sensor)
  26 Motor rotation speed detection means (rotation speed detection means)
  27 Shift position detecting means (forward / reverse detecting means)
  28 Gradient detection means
  29 Regeneration amount adjustment switch
  30 Brake frequency detection means
  31 Road condition judgment means
  32 Operation characteristic judging means

Claims (5)

An electrical energy source mounted on the vehicle;
An electric motor electrically connected to the electric energy supply source and having an output shaft coupled to a drive wheel of the vehicle;
Driving state detection means including a gradient detection means for detecting a gradient state during traveling of the vehicle and a brake frequency detection means for detecting a brake frequency of the driver;
Control means for controlling the regenerative braking force of the electric motor based on detection information from the gradient detection means in the operating state detection means;
The control means determines the driving characteristics of the driver based on detection information from a road condition determining means and a brake frequency detecting means for determining a traveling road condition of the vehicle based on a detection result of the driving condition detecting means. With driving characteristic judging means ,
The control means controls the regenerative braking force by the electric motor based on the detection result from the slope detection means, the determination information of the road condition determination means, and the determination information of the driving characteristic determination means. A regenerative braking control device for an electric vehicle. The driving state detection means has vehicle speed detection means for detecting the vehicle speed of the vehicle, and steering angle detection means for detecting the steering angle of the vehicle,
The road condition determining means determines a type of a traveling road of the vehicle based on a vehicle speed detected by the vehicle speed detecting means and a steering angle detected by the steering angle detecting means. Item 2. A regenerative braking control device for an electric vehicle according to Item 1. An electrical energy source mounted on the vehicle;
An electric motor electrically connected to the electric energy supply source and having an output shaft coupled to a drive wheel of the vehicle;
Driving state detecting means including a gradient detecting means for detecting a gradient state during traveling of the vehicle and a brake frequency detecting means for detecting a brake frequency of the driver;
Control means for controlling the regenerative braking force of the electric motor based on detection information from the gradient detection means in the operating state detection means;
The control means comprises driving characteristic determination means for determining the driving characteristic of the driver of the vehicle based on the detection result of the driving state detection means;
The control means controls the regenerative braking force by the electric motor based on the detection result from the gradient detection means and the judgment information of the driving characteristic judgment means, and the regenerative braking control of the electric vehicle, apparatus. The driving state detecting means includes an accelerator opening detecting means for detecting an accelerator opening of the vehicle, and a brake operation detecting means for detecting an operating state of a brake of the vehicle,
The brake frequency detection means detects the brake frequency based on detection information from the brake operation detection means;
The driving characteristic determining means determines the driving characteristic based on the accelerator opening detected by the accelerator opening detecting means and the brake operation frequency detected by the brake frequency detecting means. The regenerative braking control device for an electric vehicle according to claim 3. The control means has storage means for determining the regenerative braking force by the electric motor according to the detection result of the gradient detection means, reads out the regenerative braking force corresponding to the detection result from the storage means, The regenerative braking control device for an electric vehicle according to any one of claims 1 to 4, wherein the regenerative braking force by the electric motor is controlled so as to be a regenerative braking force .

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