JP2001069606A - Hybrid vehicle controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid the inversion of drive/regeneration values between a transmission side device and a reception side control device, when a motor controller receives the drive/regeneration value by pulse width modulation and realize smooth drive control. SOLUTION: A hybrid vehicle has an engine 1 operated by fuel energy, a motor 2 operated by electrical energy, an engine controller 4 which controls the engine 1 and a motor controller 5 which controls the motor 2. The engine controller 4 transmits control signals for the drive or regeneration control of the motor 2 to the motor controller 5 by pulse width modulation. If the width of the pulse signal is within a predetermined range, the drive/regeneration control value is set to zero.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control device for a hybrid vehicle, and more particularly to a hybrid vehicle having a feature of transmitting and receiving a control amount between an engine control device for controlling an engine and a motor control device for controlling a motor. Related to the control device.

[0002]

2. Description of the Related Art Hitherto, as a driving force for running a vehicle, there has been known a hybrid vehicle including a motor operated by electric energy in addition to an engine operated by combustion energy. As one type of this hybrid vehicle, there is a parallel hybrid vehicle using a motor as an auxiliary drive source for assisting the output of the engine. This parallel hybrid vehicle performs various controls, such as assisting the output of the engine by a motor during acceleration and charging a battery by deceleration regeneration during deceleration, for example, to secure the remaining capacity of the battery. In addition, it is possible to satisfy the driver's demands (for example, JP-A-7-123509). By the way, in such a hybrid vehicle, since the engine and the motor are provided as driving forces, control of the engine and the motor is generally complicated. Therefore, since the load of the drive control process is too large with one control device, the hybrid vehicle includes a plurality of control devices and distributes the load of the drive control. The drive control is realized by the plurality of control devices performing in cooperation with each other. Therefore, transmission and reception of values necessary for drive control are performed between the control devices by communication. Communication methods between the control devices include serial communication, parallel communication, pulse width modulation communication, and the like. Pulse width modulation (PWM: Pulse Widt) is performed in consideration of the communication speed, information amount, circuit cost, and the like.
h Modulation) communication may be used. Here, the pulse width modulation is performed by making the period constant and changing the ratio of “1” and “0” of the pulse in accordance with the value to be modulated. In the pulse width modulation, a pulse width occupying an output cycle is called a duty (Duty).
Further, as a control device provided for distributing the load of the drive control, there are an engine control device for controlling an engine and a motor control device for controlling a motor. In some cases, a control signal (required motor output) for driving or regenerating the motor is transmitted from the engine control device to the motor control device using the pulse width modulation signal between the two control devices. The pulse width corresponding to the required motor output value indicates a region in which the first region regenerates the motor,
The region indicated by indicates a region for driving the motor. Then, a contact point between the first region and the second region (hereinafter, “driving / regeneration zero point”) has a pulse width for setting the driving / regeneration amount of the motor to zero.

[0003]

Since the modulated signal obtained by the pulse width modulation is transmitted as an analog signal represented by the pulse width, the signal before the modulation and the signal subjected to the pulse width modulation are demodulated due to a communication error. Value may not match. The causes of the communication error include the accuracy of components used for transmission and reception, and the AD conversion after smoothing the pulse signal by the smoothing circuit when demodulating the pulse width modulated signal. When the engine control device transmits a value close to the drive / regeneration zero point when transmitting the required motor output value by the pulse width modulation, the motor control device on the receiving side communicates with the transmitting side due to a communication error. If demodulation is performed as a different required motor output value, this may hinder smooth drive control. This is because the motor control device recognizes regenerative control when drive control is required for the motor control device, or conversely, the motor control device recognizes regenerative control when drive control is required for the motor control device. This is because, as a result, the torque generated by the motor is in the opposite direction to the request, and the operation of the vehicle becomes unstable due to vibration or the like.

The present invention has been made in view of such circumstances, and when a motor control device receives a drive / regenerative amount by pulse width modulation, transmission and reception between a transmitting device and a receiving control device are performed. It is an object of the present invention to provide a hybrid vehicle capable of realizing smooth drive control by eliminating the reversal of the drive / regeneration amount.

[0005]

According to one aspect of the present invention, an engine (1) and a motor (2) for assisting or regenerating the driving force of the engine are provided. A control device for a hybrid vehicle comprising: an engine control device (4) for controlling the engine; a motor control device (5) for controlling the motor; A communication unit (in the embodiment, a transmission unit and a reception unit 51) for transmitting and receiving signals using a pulse width modulation signal between the motor control devices, wherein the engine control device is controlled by the communication unit to A control signal for driving or regeneratively controlling the motor from the motor control device to the motor control device, and the motor control device controls the motor based on the control signal. The control apparatus for de vehicle, the motor control device, the signal width of the pulse width modulation, the first
In the range (in the embodiment, the pulse width is 10 to 45%), the regenerative control amount is set according to the pulse width as a regeneration area for regenerating the motor, and the second range (in the embodiment, the pulse width is 45 to 45%). 55% [dead zone]), the drive / regeneration control amount is set to zero as the motor stop region, and a pulse is set as the drive region for driving the motor in the third range (pulse width 55 to 90% in the embodiment). A drive control amount is set according to the width, and the motor is controlled based on the set control amount (in the embodiment, steps S21 and S2).
2) is provided.

When the transmission-side engine control device transmits a value at which the drive / regeneration amount becomes zero using pulse width modulation,
The motor control device on the receiving side sets the drive / regeneration control amount to zero as the second range in which the pulse width is the motor stop region. As a result, the drive and the regenerative amount on the transmitting side and the receiving side do not drive at a value close to zero or the reversal of the regenerative amount does not occur, and smooth drive control can be performed.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A control device for a hybrid vehicle according to an embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an overall configuration of a parallel hybrid vehicle which is a kind of a hybrid vehicle according to an embodiment of the present invention. In this figure, reference numeral 1 denotes an engine operated by the combustion energy of fuel, and reference numeral 2 denotes a motor used in combination with the engine and operated by electric energy. The driving force of both the engine 1 and the motor 2 is transmitted to driving wheels (not shown) via a transmission (not shown) composed of an automatic transmission or a manual transmission. When the hybrid vehicle decelerates, the driving force is transmitted from the driving wheels to the motor 2, and the motor 2 functions as a generator. The motor 2 recovers the kinetic energy of the vehicle body as electric energy, and charges the battery 3 which will be described separately. It should be noted that a configuration may be adopted in which a generator for charging the battery 3 is provided separately from the driving motor 2. Here, for example, the battery 3 is configured as a high-voltage battery by connecting a plurality of modules in series with a module in which a plurality of cells are connected in series as one unit. Reference numeral 19 denotes a starter dedicated to starting the engine.

Reference numeral 4 denotes an engine control device which monitors the engine speed, the vehicle speed, and the like at predetermined intervals, and determines a mode such as motor regeneration, assist, and deceleration based on the results. Further, the engine control device 4 determines the assist / regeneration amount at the same time corresponding to the above-described modes, and outputs information on these modes and the assist / regeneration amount to the motor control device 5. Upon receiving the above information from the engine control device 4, the motor control device 5 controls a power drive unit (hereinafter abbreviated as “PDU”) 7 for driving / regenerating the motor 2 as instructed. Reference numeral 6 denotes a battery control device.
(Remaining capacity) is calculated. The battery control device 6 also controls a fan 35 installed near the battery 3 to protect the battery 3 so that the temperature of the battery 3 becomes equal to or lower than a predetermined value. Here, the engine control device 4, the motor control device 5, the battery control device 6, and the plurality of control devices are provided for distributing loads in drive control. The engine control device 4, the motor control device 5, and the battery control device 6 share the drive control and perform the drive control in cooperation. The engine control device 4, the motor control device 5, and the battery control device 6 are configured by a CPU (Central Processing Unit) and a memory, and realize the functions by executing a program for realizing the functions of the control device. .

Reference numeral 7 denotes a PDU, which is configured by connecting two switching elements in series and three in parallel. The switching element inside the PDU 7 is turned on and off by the motor control device 5, whereby the DC component of the high voltage system supplied from the battery 3 to the PDU 7 is supplied to the motor 2 via the three-phase line. Reference numeral 9
Is a 12 volt battery for driving various accessories, and this 12 V battery 9 is
Connected through. Converter 8 includes battery 3
Is supplied to the 12V battery 9 after being stepped down. Reference numeral 10 denotes a precharge contactor, reference numeral 11 denotes a main contactor, and the battery 3 and the PDU 7 are connected via these contactors. The precharge contactor 10 and the main contactor 11 are turned on and off by the motor control device 5.

Reference numeral 12 denotes a sensor for calculating the position and the number of revolutions of the motor 2, and reference numeral 13 denotes a current sensor for detecting currents Iu, Iv, Iw flowing through the three-phase line. The detection values of these sensors 12 and 13 are input to the motor control device 5.

Reference numeral 14 denotes the voltage Vpdu of the PDU7 input section.
Is a voltage sensor that detects the current Ipdu input to the PDU 7. Reference numeral 16 denotes a voltage sensor that detects a voltage on the battery 3 side. The voltage value and the current value detected by the above-described voltage and current sensors (14 to 16) are
Is input to Reference numeral 17 denotes a battery-side current sensor that detects a current flowing through the battery 3 via a contactor. The detected current value is input to the battery control device 6. As described above, the sensors 14 to 16 detect the voltage and the current on the battery 3 side via the contactors 10 and 11 and the voltage and the current on the PDU 7 side via the contactor. Further, the current detected by the current sensor 15 has a value obtained by subtracting the current flowing through the converter 8.

Next, the operation of the control device for a hybrid vehicle having the above configuration will be briefly described. First, the battery control device 6 calculates the remaining capacity based on the values of the input / output current 25, the voltage 29, and the like on the battery 3 side, and outputs the value to the motor control device 5. The motor control device 5 outputs the received remaining capacity to the engine control device 4. The engine control device 5 determines the mode (assist, regeneration, start, deceleration, etc.) and the required motor output of the motor 2 based on the remaining capacity, the engine speed, the throttle opening, the engine torque, the actual motor output of the motor, and the like. The mode and the required motor output are output to the motor control device 5.

The motor control device 5 includes the engine control device 4
When the mode and the required motor output are received from the ECU, the power on the input side of the PDU 7 (the voltage sensor 14 and the current sensor 15 in FIG. 1) becomes the required motor output received from the engine control device 5 during assist and deceleration. Feedback as described above to calculate the torque. On the other hand, during the cruise, the motor control device 5 controls the electric power value of the battery 3 (the voltage sensor 16 and the current sensor 17 in FIG. 1).
The feedback is performed so that the motor output becomes the required motor output, and the torque is calculated. When the torque is calculated in this manner, the motor control device 5 controls the PDU 7 according to the calculated torque. Further, the motor control device 5 starts
By controlling the PDU 7, engine start control by the motor 2 is performed. The motor control device 5 outputs the actual motor output to the engine control device 4. The engine control device 4, the motor control device 5, and the battery control device 6 control the engine 1, the motor 2, and the battery 3 by performing the above-described processing at predetermined timing as needed, and drive the hybrid vehicle.

Next, the configuration and operation of the engine control device 4 and the motor control device 5 related to the case where the values to be transmitted and received are performed by pulse width modulation will be described. In the present embodiment, the “requested motor output value” from the engine control device 4 to the motor control device 5 and the “actual motor output value” from the motor control device 5 to the engine control device 4 are shown as examples. Hereinafter, a case where these values are transmitted and received between the engine control device 4 and the motor control device 5 using pulse width modulation will be described.

FIG. 2 is a diagram showing in more detail the configuration relating to input / output signals to the engine control device 4 and the motor control device 5 and pulse width modulation. FIG. 2 mainly shows the configurations of the engine control device 4 and the motor control device 5 when the required motor output value for the motor 2 and the actual motor output value of the motor 2 are transmitted and received using pulse width modulation. In FIG. 2, the same reference numerals are given to the signals corresponding to the signals shown in FIG. Further, in FIG. 2, the signal (X) corresponding to the signal shown in FIG. 1 in more detail is indicated by a code obtained by connecting another code to the signal (X) by a dash (-).

As shown in FIG. 2, the engine control device 5 includes a request output calculation unit 41, a transmission unit 42, reception units 40 and 45, and an engine control unit 48. The receiving unit 40 receives and demodulates the remaining battery charge (SOC) sent as an analog value from the battery control device 6 via the motor control device 5, and outputs the digital value. The required output calculation unit 41 determines the traveling mode based on input values such as the engine speed, the state of the accelerator pedal, and the remaining battery charge. In addition, the required output calculation unit 41 determines the motor 2 based on the determined mode.
To calculate the required motor output value.

The transmitting section 42 performs pulse width modulation of the required motor output value calculated by the required output calculating section 41 and transmits a pulse width modulated signal to the motor control device 5. Further, the transmission unit 42 is configured by a pulse width determination unit 43 and a pulse generation unit 44. Here, the pulse width determination unit 43 determines a pulse width (duty: duty) when the required motor output value calculated by the required output calculation unit 41 is subjected to pulse width modulation.
Duty). At this time, the pulse width determination unit 43
When the drive / regeneration amount is zero, the pulse width is determined to be the center value of the preset pulse width range for this value. The pulse generator 44 forms the pulse width determined by the pulse width determiner 43 at a predetermined cycle and outputs the pulse width.

The receiving section 45 receives and demodulates the actual motor output value sent from the motor control device 5 after pulse width modulation. The receiving unit 45 includes an AD converting unit 46 and a demodulating unit 47. Here, the AD converter 46
After smoothing a pulse-width modulated signal with a smoothing circuit such as a CR circuit, the signal is AD-converted. Demodulation unit 47
Calculates the actual motor output value corresponding to the pulse width based on the characteristics of FIG. 4 described separately from the pulse width digitized by the AD converter 46. At this time, if the pulse width is within a preset pulse width range,
A demodulation process for zero regeneration is performed. Engine control unit 48
Determines the torque required of the engine using the calculation result of the required output calculation unit 41 and the actual motor output value demodulated by the reception unit 45. Further, the engine control unit 48 controls the driving of the engine so that the determined torque is obtained.

The motor control device 5 includes receiving units 50 and 51,
A PDU control unit 54 and a transmission unit 55 are provided. Receiver 50
Receives and demodulates the remaining battery charge (SOC) sent as an analog value from the battery control device 6 and outputs it as a digital value. The receiving unit 51 receives and demodulates a request motor output value transmitted from the engine control device 4 by pulse width modulation. The receiving unit 52 includes an AD converting unit 52 and a demodulating unit 53. Note that the AD converter 52 and the demodulator 53 perform the same processing as the AD converter 46 and the demodulator 47 in the engine control device 4, respectively. The PDU control unit 54 controls the PDU 7 so that the power value on the input side of the PDU 7 or the power value of the battery 3 becomes the required motor output value. Further, the PDU control unit 54 calculates the actual motor output value from the power value on the input side of the PDU 7. The transmission unit 55 performs pulse width modulation on the actual motor output value calculated by the PDU control unit 54, and transmits a pulse width modulated signal to the engine control device 4. The transmitting section 55 includes a pulse width determining section 56 and a pulse generating section 57. Note that the pulse width determination unit 56 and the pulse generation unit 57 perform the same processing as the pulse width determination unit 43 and the pulse generation unit 44 in the engine control device 4.

Next, the operation of the engine control device 4 and the motor control device 5 will be described with reference to FIG. 3, focusing on the transmission and reception of the required motor output value and the actual motor output value using pulse width modulation. 3A shows the control operation of the engine control device 4, and FIG. 3B shows the control operation of the motor control device 5. The operation shown in FIG. 3 is started when the start of the engine 1 is completed, and the ignition switch is turned “OFF”.
Until the above, each step shown in FIG. 3 is repeatedly performed at a predetermined cycle.

The engine control unit 4 senses a sensor detection value input to the engine control unit 4 and sets it in a predetermined memory (step S11). The sensor detection value input to the engine control device 4 includes a signal 33 such as a state of an accelerator pedal and a vehicle speed, a signal 34-1 such as an engine speed and an engine temperature from an engine, and a battery control via the motor control device 5. The remaining capacity of the battery sent from the device 6 and the like. The remaining capacity of the battery is sent as a pulse width modulated analog signal. Therefore, the receiving unit 40 performs analog-to-digital conversion on the pulse width of the input signal, and performs demodulation processing for obtaining the remaining capacity from the pulse width by using a table or a conversion formula showing the relationship shown in FIG. The receiving unit 40 stores the modulation result in a predetermined memory.

The required output calculation unit 41 determines a traveling mode (assist, regeneration, deceleration, etc.) based on the engine speed, the accelerator pedal state, the vehicle speed, the remaining capacity of the battery 3 and the like input to the engine control unit 5. I do. In addition, the required output calculation unit 41 determines the motor 2 based on the determined mode.
Is calculated (step S12).
That is, the required output calculation unit 41 obtains these values by referring to the memory that stores the engine speed, the state of the accelerator pedal, the remaining capacity of the battery 3, and the like. Further, the request output calculation unit 41 determines the traveling mode with reference to the values of the flags indicating various statuses in the engine control device 4. Further, the required output calculating unit 41 calculates a required driving force according to the mode, and outputs the required driving force to the engine 1 and the motor 2.
Determine the distribution of driving force to the vehicle. The request output calculation unit 41
The required driving force of the engine and the required motor output value are set in a predetermined memory.

The transmitting section 42 performs pulse width modulation on the required motor output value set in a predetermined memory and transmits a signal 32-1 at a predetermined cycle (step S13). Here, the relationship between the required motor output value and the pulse width will be described with reference to FIG. In the present embodiment, the request output calculation unit 41
Calculates the required motor output value to the motor 2 by electric power [kW], and its fluctuation range is from +10 [kW] to -10 [kW].
And The required motor output indicates the drive power of the motor when the value is positive and the regenerative power of the motor when the value is negative with respect to the drive / regeneration amount of zero. Therefore, the motor control device 5 that performs control using this value performs the drive control of the motor if the drive value is a positive value and performs the regenerative control of the motor if the value is a negative value after the drive / regeneration amount is zero. In other words, the motor control device 5 reverses the control direction at the value zero. As shown in FIG. 4, the required motor output value is −10 [kW] or more and 0
A pulse width of 10 to 45% is linearly set for a value less than [kW] (regeneration amount), and a pulse width of 5 is set for a required motor output value greater than 0 [kW] and less than +10 [kW] (drive amount).
5-90% is set to linear. For a required motor output value of zero (drive / regeneration amount is zero), the pulse width is set within a predetermined range (45% to 55%: hereinafter referred to as a "dead zone"). This dead zone depends on the component accuracy of the transmitting unit 42 of the engine control device 4 on the transmitting side and the transmitting unit 42.
The accuracy of the pulse width determined by the resolution of the pulse generation unit 44 in the unit, the component accuracy of the reception unit 51 of the motor control device 5 on the receiving side, and the resolution of the AD conversion unit 52 in the reception unit 51 determine the pulse width. Set based on demodulation accuracy.
In FIG. 4, the safety factor is set to 1.5 for the accuracy of ± 2%, and ± 5%.
% Range.

The pulse width determination section 43 converts the pulse width with respect to the required motor output into a conversion table as shown in FIG.
Alternatively, a conversion formula is provided, and the pulse width is determined from the required motor output using these formulas. Note that the pulse width determination unit 43
Converts the pulse width to the median value of 50% of the dead zone (45% to 55%) when the required motor output value is zero for the drive / regeneration amount. For this reason, the conversion table or the conversion formula is set so that when the required motor output value is zero for the drive / regeneration amount, the pulse width is 50% of the median of the dead zone (45% to 55%). The pulse width determination unit 43 outputs the obtained pulse width to the pulse generation unit 44. When a digital value related to the pulse width is input, the pulse generation unit 44 sets the value in an internal register. Further, the pulse generation unit 44
An analog signal having a pulse width of the value set in the register is generated and output every predetermined period (for example, 500 [μs]).

In the motor control device 5, the receiving unit 51
Receives and demodulates the pulse width modulated request motor output value (step S21). That is, A in the receiving unit 51
The D conversion unit 52 smoothes the input pulse signal by a smoothing circuit such as an RC circuit, converts the ratio of the pulse width of a predetermined voltage or more (Duty) to the cycle of the input signal into a digital value, and outputs the digital value to the demodulation unit 53. The AD converter 52 performs the above operation in accordance with the modulation cycle. The demodulation unit 53 includes a conversion table or a conversion formula in which the required motor output value with respect to the pulse width has the relationship shown in FIG. 4, and demodulates the pulse width to the required motor output using these. When the pulse width is in the dead zone (45% to 55%), the demodulation unit 53 demodulates the drive / regeneration amount to zero as the required motor output value. Therefore, the conversion table or the conversion formula is set so that the required motor output value becomes zero when the pulse width is in the range of the dead zone. The demodulation unit 53 sets the demodulated required motor output value in a predetermined memory. Thereby, the regenerative control amount according to the pulse width is set as the regenerating region for regenerating the motor 2 in the pulse width of 10% to 45%, and the pulse width is set as the driving region for driving the motor 2 in the pulse width of 55% to 90%. The drive control amount is set accordingly. Then, in the pulse width of 45% to 55%, the drive / regeneration control amount is set to zero as the motor stop region. As shown in the characteristics of FIG. 4, communication is performed within a pulse width range of 10% to 90%. Therefore, in consideration of accuracy, when the pulse width is equal to or more than 95% or equal to or less than 5%, the demodulation unit 53 also performs processing for determining that there is a communication abnormality due to a disconnection of a communication line or the like. Since the modulation period of the reception unit 51 is generally shorter than the operation period of the PDU control unit 54 that performs complicated control, the demodulation unit 53 requests the average value or the median value of a predetermined number of demodulation results to request the motor. The output value may be set in a predetermined memory.

The PDU control unit 54 controls the PDU 7 so that the power value on the input side of the PDU 7 or the power value of the battery 3 becomes the required torque output value (step S22).
That is, the PDU control unit 54 obtains the required motor output value by referring to the predetermined memory. When the required motor output value is zero, the PDU control unit 54 sets the motor 2 so that both the drive control amount and the regenerative control amount become zero.
The control signal 23 is output to the DU7. When the required motor output value is a positive value, the PDU control unit 54 obtains the current drive power from the measured values from the voltage sensor 14 and the current sensor 15 provided on the PDU 7 side, and this drive power is Feedback control is performed on the PDU 7 so as to be an output value. If the required motor output value is a negative value, P
The DU control unit 54 obtains the current regenerative power from the measured values from the voltage sensor 16 and the current sensor 17 provided on the battery 3 side, and performs feedback control on the PDU 7 so that the regenerative power becomes the required motor output. That is, the PDU control unit 54 reverses the direction of the control when the drive / regeneration amount is zero. In the control of the PDU 7, the PDU control unit 54 also performs a process of correcting the required motor output value in consideration of the remaining capacity of the battery 3 received by the receiving unit 50. In addition, the PDU control unit 54 sets the PDU 7
The actual motor output is calculated from the power value on the input side of. At this time, the actual motor output value during driving is calculated as a positive value, and the actual motor output value during regeneration is calculated as a negative value. Then, the actual motor output value when the driving / regeneration of the motor 2 is not performed becomes zero. The PDU control unit 54 sets the calculated actual motor output value in a predetermined memory. As shown in the characteristics of FIG. 6, the pulse width is 10% to 90%.
It communicates in the range of%. Therefore, in consideration of the accuracy, when the pulse width is 95% or more or 5% or less, the receiving unit 50 also performs a process of determining that there is a communication abnormality due to a disconnection of the communication line or the like.

The transmitting section 55 performs pulse width modulation on the actual motor output value set in a predetermined memory, and outputs the signal 3 at a predetermined cycle.
2-2 is transmitted (step S23). Here, the relationship between the actual motor output value and the pulse width will be described with reference to FIG. In the present embodiment, the PDU control unit 54 calculates the actual motor output value of the motor 2 using the torque [kgfm].
The variation range is from +10 [kgfm] to -10 [kgf
m]. Further, in the idling state, the engine control device 5 that performs control using this value controls the engine output to a predetermined torque value when the actual motor torque is zero, and reduces the engine torque if the value is a positive value. If the control is a negative value, control to increase the engine torque is performed. That is, the engine control device 4 reverses the direction of the control at an actual motor output value of zero. Similarly to FIG. 4, FIG. 5 shows that the actual motor output value is -10 [kgfm] or more and less than 0 [kgfm] (regenerative torque), and the pulse width is 1
0 to 45% is set to linear and the actual motor output value is 0
Greater than [kW] and less than +10 [kW] (drive torque)
, A pulse width of 55 to 90% is set linearly. For an actual motor output value of zero, the pulse width is set within a predetermined range (45% to 55%: also called a "dead zone"). The dead zone is set based on the accuracy of the pulse width generated by the transmission unit 55 and the demodulation accuracy of the reception unit 45, as described with reference to FIG. Also, as compared with the transmission unit 42 in the engine control device 4, the transmission unit 55 in the motor control device 5 has a different value to be modulated, and has a different relationship between the value to be modulated and the pulse width after modulation. Since this is only the case, the description is omitted.

In the engine control unit 5, the receiving unit 45
Receives and demodulates the pulse width modulated actual motor output value (step S14). Receiving unit 5 in motor control device 5
1, the receiving unit 45 in the engine control unit 4
Since the values to be demodulated are different and only the relationship between the pulse width and the value to be demodulated is different, the description is omitted.

The engine control unit 48 includes the request output calculation unit 4
By comparing the required motor output value calculated in 1 with the actual motor output value demodulated by the receiving unit 45, it is checked whether the motor 2 is being driven / regenerated with the requested motor output value. Further, the engine control unit 48 controls the driving of the engine such that the engine torque calculated by the required output calculation unit 41 is output from the engine (step S
15). In the idling state, when the actual motor output value is zero, the engine control unit 48 controls the engine so that the engine output has a predetermined torque (a predetermined rotation speed). The engine control unit 48 outputs a control signal 34-2 for reducing the amount of air supplied to the engine to reduce the engine torque if the actual motor output value is a positive value, and outputs the engine torque if the actual motor output value is a negative value. Signal 34-2 for increasing the amount of air supplied to the engine in order to increase
Is output.

As described above, the engine control unit 4 and the motor control unit 5 perform control processing including pulse width modulation of the required motor output value and the actual motor output value, and transmission and reception. As described above, the engine control device 4 performs the pulse width modulation with the drive / regeneration amount zero in the calculated required motor output value as the median value of the preset dead zone for this value. Further, the motor control device 5 performs a demodulation process in which the required motor output value is set to zero if the received pulse width is within a preset dead zone. This allows
When the engine control device 4 outputs zero drive / regeneration amount to the motor control device 5 using pulse width modulation, the motor control device 5 can demodulate the drive / regeneration amount as zero. Further, the engine control device 4 drives / controls using pulse width modulation.
When a value near the regeneration amount is output to the motor control device 5, the motor control device 5 can demodulate the drive / regeneration amount without inversion. Therefore, there is no misalignment between the motor control device 5 and the engine control device 4 regarding the sign of the drive / regeneration amount of zero and the value in the vicinity thereof. Even though the engine control 4 continuously transmits the drive / regeneration amount of zero, the motor control device 5 determines a value other than zero due to an error,
For example, assume that demodulation is performed as a value in which positive and negative alternate.
In this case, the motor control device 5 drives the motor 2 sequentially /
Outputs a control signal to regenerate. Therefore, the direction in which the torque is applied by the motor 2 is sequentially reversed. for that reason,
The resultant torque of the engine 1 and the motor 2 changes periodically, and the running of the hybrid vehicle is not smooth during running. On the other hand, in the hybrid vehicle of the present embodiment, there is no misalignment between engine control device 4 and motor control device 5 regarding zero drive / regeneration. Accordingly, there is no periodic change in the combined torque of the engine 1 and the motor 2, and the running of the hybrid vehicle becomes smoother.

Similarly, the motor control device 5 performs pulse width modulation using the obtained actual motor output value of zero as the median value of a preset dead zone for this value. On the other hand, if the received pulse width is within the preset dead zone, the engine control device 4 performs demodulation processing to set the actual motor output value to zero. Thereby, when the motor control device 5 outputs the actual motor output value zero to the engine control device 4 using the pulse width modulation, the engine control device 4 can demodulate the actual motor output value as zero. Further, when the motor control device 5 outputs a value near the actual motor output value zero using the pulse width modulation to the engine control device 4, the engine control device 4
Demodulation can be performed without inverting the sign of the actual motor output value.
Therefore, there is no misalignment between the motor control device 5 and the engine control device 4 regarding the sign of the actual motor output value zero and the sign of the value in the vicinity thereof. It is assumed that, although the motor control 5 continuously transmits the actual motor output value of zero, the engine control device 4 demodulates the value as a value other than zero, for example, a value that alternates between positive and negative due to an error. In this case, the engine control device 5 outputs a control signal that causes the torque (rotation speed) of the engine 1 to be periodic in the idling state. Therefore, the stability of the engine speed during idling is deteriorated. On the other hand, in the hybrid vehicle according to the present embodiment, since there is no misalignment between the engine control device 4 and the motor control device 5 regarding the actual motor output value zero, the stability of the engine speed during idling is improved. Become.

In this embodiment, as a hybrid vehicle to which the present invention is applied, FIG. 1 shows a parallel hybrid vehicle of a type that combines and distributes the outputs of the engine 1 and the motor 2. In such a parallel hybrid vehicle, since the drive of the engine 1 and the motor 2 is close, good drive control can be obtained by communication especially considering the drive / regeneration amount of zero according to the present invention. It is not limited to cars. For example, the present invention can be applied to various types of hybrid vehicles such as a hybrid vehicle in which power transmission is connected and disconnected by a clutch.

In the present invention, the unit of the required motor output is the electric power [KW] and the unit of the actual motor output is the torque [kgfm]. However, the present invention is not limited to this. For example, the unit of the required motor output may be torque, and the unit of the actual motor output may be electric power. Further, in the present embodiment, as shown in FIGS. 4 and 5, the relationship between the transmitted / received value other than the dead zone and the pulse width is shown as changing linearly, but is not limited to this. Alternatively, a non-linear setting may be performed in consideration of the control specification of the control device on the receiving side.

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and includes a design and the like within a range not departing from the gist of the present invention. It is.

[0035]

As described above, according to the hybrid vehicle of the present invention, the following effects can be obtained. According to the present invention, when the drive / regeneration amount is zero, the engine control device performs pulse width modulation on this value to a pulse width within a preset range (dead zone) and transmits the value. If the received pulse width is within the dead zone, the motor control device on the receiving side performs demodulation processing for setting the drive / regeneration amount to zero. Accordingly, when the transmitting apparatus transmits a drive / regeneration amount of zero or a value in the vicinity thereof using the pulse width modulation, the control device on the reception side changes the drive / regeneration amount to the drive / regeneration amount to zero. The values in the vicinity can be demodulated without wrong codes. Therefore, smooth drive control can be performed.

[Brief description of the drawings]

FIG. 1 is a diagram showing a block configuration diagram of a hybrid vehicle.

FIG. 2 is a diagram illustrating in more detail a configuration related to input / output signals to an engine control device and a motor control device and pulse width modulation.

FIG. 3 is a diagram showing a control flow including communication between an engine control device and a motor control device.

FIG. 4 is a diagram illustrating a relationship between a required motor output value to a motor and a pulse width in pulse width modulation.

FIG. 5 is a diagram showing a relationship between an actual motor output of a motor and a pulse width in pulse width modulation.

FIG. 6 is a diagram illustrating a relationship between a remaining battery capacity and a pulse width in pulse width modulation.

[Explanation of symbols]

Reference Signs List 1 engine 2 motor 3 battery 4 engine control device 5 motor control device 6 battery control device 7 power drive unit (PDU) 8 converter 9 12V battery 10 precharge contactor 11 main contactor 12 rotation /
Position sensor 13, 15, 17 Current sensor 14, 16 Voltage sensor 18 Fan 19 Starter 41 Request output calculation unit 42 Transmission unit 43 Pulse width determination unit 44 Pulse generation unit 45 Receiving unit 46 AD conversion unit 47 Demodulation unit 48 Engine control unit 51 Receiver 52 AD converter 53 Demodulator 54 PDU
Control unit 55 Transmission unit 56 Pulse width determination unit 57 Pulse generation unit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 3G093 AA05 AA07 AA16 CB14 DA01 DA05 DA06 DB00 DB19 DB20 EB00 EC02 FA11 FA14 FB07 5H115 PG04 PI15 PI16 PI29 PU01 PU25 QI04 QN03 QN09 QN12 QN26 RE03 RE06 SE05 SE06 TE05 TE02 TE03 TI10 TO04 TO12 TO13 TO21 UI29

Claims (1)

[Claims] 1. A control device for a hybrid vehicle including an engine and a motor that assists or regenerates the driving force of the engine, wherein the control device includes: an engine control device that controls the engine; A motor control device for controlling, and communication means for transmitting and receiving a signal using a pulse width modulation signal between the engine control device and the motor control device, wherein the engine control device is transmitted from the engine control device by the communication means. A control device for a hybrid vehicle in which a control signal for driving or regenerating a motor is transmitted to the motor control device, and the motor control device controls the motor based on the control signal, wherein the motor control device has the pulse width When the signal width of the modulation is in the first range, a regenerative region for regenerating the motor is used according to the pulse width. A raw control amount is set, a drive / regeneration control amount is set to zero in the second range as the motor stop region, and a drive control amount is set as a drive region for driving the motor in the third range according to the pulse width. A control device for a hybrid vehicle, wherein the control device sets and controls the motor based on the set control amount.