JP6445157B2 - Power conversion control device, battery control device, drive control subsystem - Google Patents

Description

  The present invention relates to a power conversion control device, a battery control device, and a drive control subsystem including them.

Conventionally, in AGV (Automatic Guided Vehicle), a battery system including a load (motor), an inverter, a converter, a power receiving unit, a main power source, a sub power source, and a power source switch is known (Patent Document 1). When the load driving time reaches a predetermined correction start time, the battery system measures the voltage between the terminals when the main power supply is charged / discharged with a preset inspection current, and based on the measured value. Then, an error in the state of charge (SOC) of the battery obtained by current integration is corrected.

JP 2012-212510 A

  In the battery system of Patent Document 1, a sub-power source is necessary to maintain the power supply state to the load even when the main power source is charged / discharged with the inspection current, and a changeover switch for switching between the main power source and the sub-power source. Is also necessary. Therefore, there is a problem that the system configuration becomes complicated and costs increase.

A power conversion control device according to the present invention is connected to a battery control device that controls charging / discharging of a battery, and controls a power conversion circuit that supplies an alternating current to a motor that drives a vehicle using a direct current supplied from the battery. The power conversion circuit has a switching element of a three-phase upper and lower arm, and when the vehicle is running , the upper arm or the lower arm of all phases of the switching element is turned on during a three-phase short circuit. Or when the switching is stopped when all of the switching elements are stopped, the control state of the power conversion circuit is determined to be a zero current control state in which the current value of the direct current is zero, and is detected by the battery control device. a permission signal for permitting the start of error correction to the state of charge of the battery has to transmit to the battery control device, the running of the vehicle Even the a time of switching stopped, the induced voltage of the motor when the predetermined value or more, not to transmit the permission signal. A battery control device according to the present invention is connected to the power conversion control device and controls charging / discharging of the battery. The battery control device detects a state of charge of the battery, and the permission signal is received from the power conversion control device. When transmitted, it performs error correction for the state of charge of the battery. A drive control subsystem according to the present invention includes the power conversion control device and the battery control device described above.

  According to the present invention, it is possible to correct the detection error of the state of charge of the battery while the vehicle is running without increasing the cost.

It is a figure which shows the structure of the electric vehicle carrying the power conversion control apparatus and battery control apparatus which concern on one Embodiment of this invention. It is a figure showing composition of a vehicle drive system concerning one embodiment of the present invention. It is a figure which shows the detail of a rotary electric machine and a power converter device. It is a figure which shows the detail of a battery apparatus. It is a figure which shows an example of the conventional CAN message. It is a figure which shows an example of the conventional CAN message transmission / reception. It is a figure which shows an example of the CAN message of a SOC detection error correction request signal. It is a figure which shows an example of CAN message transmission / reception of a SOC detection error correction request signal. It is a figure which shows an example of the CAN message of a SOC detection error correction permission signal. It is a figure which shows an example of CAN message transmission / reception of a SOC detection error correction permission signal. It is a figure which shows the structure of the vehicle drive system which provided the local CAN communication line in addition to the BUS line of CAN communication. It is a figure which shows the relationship between the open end voltage of a high voltage battery, and SOC. It is a figure which shows the mode of the time change of the SOC detection error after IGN ON. It is a figure which shows the mode of a time change of an SOC detection error at the time of performing IGN ON, IGN OFF, and IGN ON continuously. It is a figure which shows an example of the detection error of the current sensor with respect to input current. It is a figure which shows an example of the detection error of the current sensor with respect to the input current after SOC detection error correction | amendment.

  Hereinafter, a power conversion control device, a battery control device, and a drive control subsystem according to an embodiment of the present invention will be described. FIG. 1 is a diagram showing a configuration of an electric vehicle 1 equipped with a power conversion control device and a battery control device according to an embodiment of the present invention. The electric vehicle 1 is an example of an electric vehicle having a general configuration. In this embodiment, the electric vehicle 1 shows an example of front wheel drive, but it may be a rear wheel drive or a four wheel drive vehicle.

  The rotating electrical machine 30 is mechanically connected to the axles 40R and 40L via the gear box 40. The axles 40R and 40L are connected to driving wheels (front wheels) 10FR and 10RL, respectively. The drive wheels 10FR and 10RL drive the electric vehicle by transmitting the output of the rotating electrical machine 30 via the gear box 40 and the axles 40R and 40L to the ground as a driving force. The driven wheels (rear wheels) 10RR and 10RL are connected to the differential gear 60 by axles 70L and 70R, respectively.

  The vehicle controller (VCM) 100 is a controller that controls the electric vehicle 1 in an integrated manner. The vehicle controller 100 is connected to a power conversion control unit (MCU) 210, a battery control unit (BCU) 410, a charger control unit 510, and a converter control unit 610 through a CAN communication BUS line 110. With this connection, CAN messages can be transmitted and received among the vehicle controller 100, the power conversion control device 210, the battery control device 410, the charger control device 510, and the converter control device 610.

  The power conversion control device 210 is connected to the power conversion circuit 220. The power conversion circuit 220 is connected to the rotating electrical machine 30 by the three-phase harnesses 9U, 9V, and 9W, and can exchange AC power with the rotating electrical machine 30 through these. The power conversion circuit 220 is connected to the high voltage battery 420 by the DC harnesses 9P and 9N, and can exchange DC power with the high voltage battery 420 through the DC harnesses 9P and 9N. Yes.

  The DC harness 9P includes a positive electrode relay 9PS, a precharge resistor 9PPR, and a precharge relay 9PPS. The precharge resistor 9PPR and the precharge relay 9PPS are connected in series, and these are attached in parallel with the positive electrode relay 9PS. The DC harness 9P can connect and disconnect the DC power supplied from the high voltage battery 420 at any time by switching the connection state of the positive electrode relay 9PS and the precharge relay 9PPS. The DC harness 9N includes a negative relay 9NS. The DC harness 9N can connect and disconnect the DC power supplied from the high voltage battery 420 at any time by switching the connection state of the negative relay 9NS.

  The battery control device 410 is connected to the high voltage battery 420. The high voltage battery 420 is connected to the charger 500 by harnesses 9P1 and 9N1, and can exchange DC power with the charger 500 through these.

  The charger control device 510 is connected to the charger 500. The charger 500 is connected to harnesses 9P3 and 9N3 for connection to a charging stand 800 that is an external power source. In a state where the charger 500 and the charging stand 800 are connected to each other via the harnesses 9P3 and 9N3, the charger control device 510 controls the electric power from the charging stand 800, whereby the high voltage battery 420 is charged. In the present embodiment, the case of charging will be described. However, when the charger 500 has a power supply function, the power of the high voltage battery 420 can be supplied to the outside.

  Converter control device 610 is connected to DCDC converter 600. The DCDC converter 600 is connected to the high voltage battery 420 by the harnesses 9P2 and 9N2 connected to the harnesses 9P1 and 9N1, respectively. Thus, the DC power supplied from the high voltage battery 420 can be appropriately converted by the DCDC converter 600 and output to the low voltage battery 700.

  The low voltage battery 700 has an output voltage of about 12 to 24V, for example. The low voltage battery 700 is connected to the DCDC converter 600 and is appropriately charged with the DC power from the DCDC converter 600.

  FIG. 2 is a diagram showing a configuration of a vehicle drive system according to an embodiment of the present invention. The vehicle drive system of FIG. 2 includes the rotating electrical machine 30, the vehicle controller 100, the charger 500, the charger control device 510, the DCDC converter 600, the converter control device 610, the low voltage battery 700, the power conversion device 200, and the battery of FIG. Device 400. The power conversion device 200 includes the power conversion control device 210 and the power conversion circuit 220 in FIG. 1, the smoothing capacitor 200C, and the current sensor 20C. The battery device 400 includes the battery control device 410, the high voltage battery 420, and the DC harnesses 9P and 9N shown in FIG. The power conversion control device 210 and the battery control device 410 may be collectively referred to as a drive control subsystem.

  When the driver turns on the travel start switch of the electric vehicle 1 (hereinafter, IGN ON), the vehicle controller 100 transmits an activation command to the BUS line 110 of CAN communication. When the power conversion control device 210 and the battery control device 410 receive the start command transmitted from the vehicle controller 100 from the BUS line 110, the power conversion control device 210 and the battery control device 410 each start a predetermined start sequence.

  When the battery control device 410 starts the startup sequence, SOC detection error correction and initial SOC value detection described later are performed. Subsequently, the negative relay 9NS is turned on (connected), and then the precharge relay 9PPS is turned on (connected). Thus, conduction between the high voltage battery 420 and the power conversion circuit 220 is started, and a charging current flows to the smoothing capacitor 200C through the precharge resistor 9PPR. Thereafter, when the voltage across the smoothing capacitor 200C reaches a certain value or more, the positive relay 9PS is turned on (connected) and the precharge relay 9PPS is turned off (disconnected). This operation is for preventing an excessive inrush current from flowing through the smoothing capacitor 200C.

  When the driver turns off the travel start switch of the electric vehicle 1 (hereinafter IGN OFF), the vehicle controller 100 transmits an end command to the BUS line 110 of CAN communication. When the power conversion control device 210 and the battery control device 410 receive the end command transmitted from the vehicle controller 100 from the BUS line 110, the power conversion control device 210 and the battery control device 410 each start a predetermined end sequence. When the battery control device 410 starts an end sequence, the negative relay 9NS and the positive relay 9PS are turned off (disconnected), and the high voltage battery 420 is disconnected from the power conversion circuit 220.

  FIG. 3 is a diagram illustrating details of the rotating electrical machine 30 and the power conversion device 200.

  The power conversion circuit 220 converts the DC current (DC power) supplied from the high voltage battery 420 into AC current (AC power) and supplies it to the rotating electrical machine 30 under the control of the power conversion control device 210. The power conversion circuit 220 can also charge the high voltage battery 420 by converting AC power generated by the rotation of the rotating electrical machine 30 into DC power.

  The power conversion circuit 220 includes three-phase upper arm switching elements 20UU, 20VU, and 20WU corresponding to the U-phase, V-phase, and W-phase, and three-phase lower-arm switching corresponding to the U-phase, V-phase, and W-phase, respectively. It has elements 20UL, 20VL, and 20WL. These switching elements are composed of, for example, IGBTs or MOSFETs.

  Harnesses 9U, 9V, and 9W are provided between the power conversion circuit 220 and the rotating electrical machine 30. Harness 9U electrically connects U-phase coil 30U of rotating electrical machine 30 and U-phase connection terminal 20U of power conversion circuit 220. U-phase connection terminal 20U is provided between U-phase upper arm switching element 20UU and U-phase lower arm switching element 20UL. The harness 9V electrically connects the V-phase coil 30V of the rotating electrical machine 30 and the V-phase connection terminal 20V of the power conversion circuit 220. V-phase connection terminal 20V is provided between V-phase upper arm switching element 20VU and V-phase lower arm switching element 20VL. The harness 9W electrically connects the W-phase coil 30W of the rotating electrical machine 30 and the W-phase connection terminal 20W of the power conversion circuit 220. W-phase connection terminal 20W is provided between W-phase upper arm switching element 20WU and W-phase lower arm switching element 20WL.

  The rotating electrical machine 30 converts an electrical output into a mechanical output by rotationally driving a rotor (not shown) using AC power input from the power conversion circuit 220 via the harnesses 9U, 9V, and 9W (power running). . Further, when the rotor is rotated by applying mechanical input to the rotating electrical machine 30 from the outside, the rotating electrical machine 30 acts as a generator, and electrical output is possible (regeneration).

  The magnetic pole position sensor 30 </ b> R detects the rotor magnetic pole position of the rotating electrical machine 30. Information on the rotor magnetic pole position detected by the magnetic pole position sensor 30R is output to the power conversion control device 210. The thermistor 30 </ b> T detects the coil temperature of the rotating electrical machine 30. Information on the coil temperature detected by the thermistor 30T is output to the power conversion control device 210. The current sensor 20 </ b> C is attached to the harnesses 9 </ b> U, 9 </ b> V, and 9 </ b> W, and detects a current value flowing between the power conversion circuit 220 and the rotating electrical machine 30. Information on the current of each phase detected by the current sensor 20 </ b> C is output to the power conversion control device 210.

  When the rotating electrical machine 30 is powered, the switching operation of the six switching elements 20UU, 20UL, 20VU, 20VL, 20WU, and 20WL of the power conversion circuit 220 is performed according to the magnetic pole position of the rotor under the control of the power conversion controller 210 I do. Thereby, the three-phase AC power having the necessary phase and amplitude is supplied to the U-phase coil 30U, the V-phase coil 30V, and the W-phase coil 30W of the rotating electrical machine 30, respectively. Then, the rotating electrical machine 30 converts the input AC power into a machine output and outputs it. At this time, the power conversion control device 210 performs feedback control based on the detection result of the current that actually flows through the rotating electrical machine 30, thereby controlling the alternating current with the target current value to flow stably through the rotating electrical machine 30.

  In addition, the power conversion control apparatus 210 can also monitor the coil temperature of the rotary electric machine 30 detected by the thermistor 30T, and can also perform control based on the monitoring result. For example, when the coil temperature exceeds a certain threshold value, the AC power input to the rotating electrical machine 30 is limited to a predetermined value or less in order to prevent the rotating electrical machine 30 from burning out.

  FIG. 4 is a diagram illustrating details of the battery device 400.

  The high voltage battery 420 outputs DC power to the power conversion device 200 or inputs DC power from the power conversion device 200 via the DC harnesses 9P and 9N. In the present embodiment, an example in which the positive relay 9PS, the negative relay 9NS, the precharge relay 9PPS, and the precharge resistor 9PPR are stored in the battery device 400 is shown, but these may be arranged outside the high voltage battery 420. is there. The harnesses 9P1 and 9N2 electrically connect the high voltage battery 420, the charger 500, and the DCDC converter 600.

  The high voltage battery 420 includes n battery cells 420 (1) to 420 (n). n is an arbitrary integer of 1 or more. In the high voltage battery 420 of this embodiment, all of the battery cells 420 (1) to 420 (n) may be connected in series or in parallel. Moreover, it is good also as a combination of series and parallel. One or a plurality of temperature sensors (not shown) are attached to the high voltage battery 420, and battery temperature information detected by the temperature sensors is input to the battery control device 410.

  The voltmeter 400V measures the total voltage of the high voltage battery 420. The voltmeter 400V may measure the total voltage of the high voltage battery 420 by detecting and adding the voltages of the battery cells 420 (1) to 420 (n), or simply measure the battery cell 420 (1). The total voltage of the high-voltage battery 420 may be measured by measuring the voltage between the positive electrode and the negative electrode of 420 (n). The ammeter 400 </ b> A measures a current input / output to / from the high voltage battery 420. Information on the total voltage of the high-voltage battery 420 detected by the voltmeter 400V and information on the current of the high-voltage battery 420 detected by the ammeter 400A are input to the battery control device 410.

  FIG. 5 is a diagram illustrating an example of a conventional CAN message transmitted / received among the vehicle controller 100, the battery control device 410, and the power conversion control device 210. In FIG. 5, an ID for identification is assigned to each transmission / reception message.

  For example, the vehicle controller 100 transmits a message of the target torque (ID: 010) in the transmission message list to the BUS line 110 of CAN communication at an arbitrary time interval. Since the message reception list of the power conversion control device 210 has the target torque (ID: 010), the power conversion control device 210 receives the message of the target torque. Then, the torque of the rotating electrical machine 30 is controlled based on the target torque value indicated by the received message.

  Further, for example, the battery control device 410 transmits a message of the battery state (ID: 040) in the transmission message list to the BUS line 110 of CAN communication at an arbitrary time interval. Since there is a battery state (ID: 040) in the message reception list of the vehicle controller 100, the vehicle controller 100 receives this battery state message and uses it for controlling the electric vehicle 1. The battery status (ID: 400) message includes, for example, battery power (charge / discharge) information, battery total voltage information, battery current information, battery SOC information, battery temperature information, and the like. .

  FIG. 6 is a diagram illustrating an example of conventional CAN message transmission / reception in the vehicle controller 100, the battery control device 410, and the power conversion control device 210. The actual signal flow in the transmission / reception of the CAN message described above with reference to FIG. 5 will be described below with reference to FIG.

  From the vehicle controller 100, the message of the target torque (ID: 010) shown in FIG. 5 is output as indicated by an arrow 110AS. The target torque message flows on the CAN communication BUS line 110 and is input to the power conversion control device 210 as indicated by an arrow 110AR.

  Further, the battery control device 410 outputs a message of the battery state (ID: 040) shown in FIG. 5 as indicated by an arrow 410AS. The battery status message flows on the CAN communication BUS line 110 and is input to the vehicle controller 100 as indicated by an arrow 410AR.

  FIG. 7 is a diagram illustrating an example of a CAN message of an SOC detection error correction request signal transmitted / received among the vehicle controller 100, the battery control device 410, and the power conversion control device 210.

  When the electric vehicle 1 is turned on, the conduction between the high voltage battery 420 and the power conversion circuit 220 is started as described above, and a predetermined activation sequence is started in the power conversion control device 210 and the battery control device 410. When a predetermined time has elapsed since IGN ON, battery control device 410 transmits a message of SOC detection error correction request (ID: 042) in the transmission message list to BUS line 110 of CAN communication. Since the message reception list of the vehicle controller 100 and the message reception list of the power conversion control device 210 include an SOC detection error correction request (ID: 042), the vehicle controller 100 and the power conversion control device 210 perform the SOC detection error correction. Each request message is received. Thereby, the vehicle controller 100 and the power conversion control device 210 can respectively know that the battery control device 410 requests correction of the SOC detection error.

  FIG. 8 is a diagram illustrating an example of CAN message transmission / reception of the SOC detection error correction request signal in the vehicle controller 100, the battery control device 410, and the power conversion control device 210. The actual signal flow in the transmission / reception of the CAN message described above with reference to FIG. 7 will be described below with reference to FIG.

  The battery control device 410 outputs a message of the SOC detection error correction request (ID: 042) shown in FIG. 7 as indicated by an arrow 410BS. The SOC detection error correction request message flows on the BUS line 110 of CAN communication, and is input to the power conversion control device 210 and the vehicle controller 100 as indicated by arrows 410BR1 and 410BR2.

  As described above, the battery control device 410 requests permission to start error correction with respect to the SOC of the high voltage battery 420 after a predetermined time has elapsed after the conduction between the high voltage battery 420 and the power conversion circuit 220 is started. As a request signal, an SOC detection error correction request message is transmitted. This SOC detection error correction request message is received by the power conversion control device 210 and the vehicle controller 100.

  FIG. 9 is a diagram illustrating an example of a CAN message of an SOC detection error correction permission signal transmitted / received among the vehicle controller 100, the battery control device 410, the power conversion control device 210, and the converter control device 610.

  When power conversion control device 210 determines that the current value of the direct current supplied from high voltage battery 420 to power conversion circuit 220 is 0 or 0, SOC detection error correction permission (ID: 090) is transmitted to the BUS line 110 of CAN communication. Since the message reception list of the battery control device 410 and the message reception list of the converter control device 610 have SOC detection error correction permission (ID: 090), the battery control device 410 and the converter control device 610 perform the SOC detection error correction. Each permission message is received. Thereby, battery control device 410 and converter control device 610 can each know that the correction of the SOC detection error is permitted, and can start the SOC detection error correction operation described later.

  Specifically, in the power conversion control device 210, the control state of the power conversion circuit 220 is a predetermined control state (zero current control state) for setting the current value of the direct current from the high voltage battery 420 to zero. It is possible to determine whether or not the current value of the direct current is 0 or 0. This zero current control state includes, for example, a three-phase short-circuit control state. The three-phase short circuit is a state in which all of the three-phase upper arm switching elements 20UU, 20VU, and 20WU of the power conversion circuit 220 or all of the three-phase lower arm switching elements 20UL, 20VL, and 20WL are simultaneously turned on. . In this three-phase short-circuit control state, current flows back between the power conversion circuit 220 and the rotating electrical machine 30. Therefore, the input / output current is zero between the high voltage battery 420 and the power conversion circuit 220.

  Further, the zero current control state includes, for example, a switching stop control state. The switching stop is a state where all of the switching elements 20UU, 20VU, 20WU, 20UL, 20VL, and 20WL of the three-phase upper and lower arms of the power conversion circuit 220 stop the switching operation. In this switching stop control state, the current between the power conversion circuit 220 and the rotating electrical machine 30 is interrupted. Therefore, the input / output current is zero between the high voltage battery 420 and the power conversion circuit 220.

  Even in the switching stop state, when the rotational speed of the rotating electrical machine 30 exceeds a certain value, the induced voltage generated by the rotating electrical machine 30 becomes equal to or higher than a predetermined diode conduction voltage. At this time, a direct current flows from the power conversion circuit 220 to the high voltage battery 420 side through the diode portions in the six switching elements 20UU, 20VU, 20WU, 20UL, 20VL, and 20WL of the power conversion device 200. The voltage battery 420 is charged. Therefore, in such a state, it is preferable not to transmit an SOC detection error correction permission message from power conversion control device 210. Specifically, when it is assumed that the rotating electrical machine 30 is at a certain value or higher in the switching stopped state, the switching electrical machine 30 is in the switching stopped state and the rotational speed of the rotating electrical machine 30 is below a certain value (that is, induction When the voltage is equal to or lower than the predetermined value, the power conversion control device 210 may transmit a message for permitting SOC detection error correction.

  In the above description, an example has been described in which the power conversion control device 210 determines a zero-current control state by transmitting a three-phase short circuit or switching stop control state and transmits a SOC detection error correction permission message. However, the vehicle controller 100 transmits a three-phase short circuit (ID: 015) or SW stop (ID: 020) message in the transmission list, and the power conversion control device 210 receives these messages, so that power conversion control is performed. The apparatus 210 may be a trigger for transmitting a message for permitting SOC detection error correction.

  When converter control device 610 receives the SOC detection error correction permission message, it stops the operation of DCDC converter 600. This prevents the low voltage battery 700 from being charged from the high voltage battery 420 via the DCDC converter 600 during the SOC detection error correction operation. Alternatively, if the value of the current flowing from the high voltage battery 420 through the harnesses 9P1 and 9N1 is greater than a certain value during voltage conversion of the DCDC converter 600, the operation of the DCDC converter 600 is stopped during the SOC detection error correction operation. You may make it do.

  FIG. 10 is a diagram illustrating an example of CAN message transmission / reception of the SOC detection error correction permission signal in the vehicle controller 100, the battery control device 410, the power conversion control device 210, and the converter control device 610. The actual signal flow in the transmission and reception of the CAN message described above with reference to FIG. 9 will be described below with reference to FIG.

  The power conversion control device 210 outputs the SOC detection error correction permission (ID: 090) message shown in FIG. 9 as indicated by an arrow 210BS. This SOC detection error correction permission message flows on the BUS line 110 of CAN communication, and is input to the battery control device 410 and the converter control device 610 as indicated by arrows 210BR1 and 210BR2.

  As described above, the power conversion control device 210 has an error with respect to the SOC of the high voltage battery 420 when the current value of the direct current supplied from the high voltage battery 420 to the power conversion circuit 220 is 0 or 0. As a permission signal for permitting the start of correction, an SOC detection error correction permission message is transmitted. This SOC detection error correction permission message is received by battery control device 410 and converter control device 610.

  As described above with reference to FIGS. 5 to 10, the CAN communication BUS line 110 includes a vehicle controller 100, a power conversion control device 210, a battery control device 410, a charger control device 510, and converter control. Various signals transmitted from the device 610 are flowing. Therefore, when the amount of signal flowing through the BUS line 110 becomes excessive, it is possible to smoothly transmit and receive the SOC detection error correction request (ID: 042) and SOC detection error correction permission (ID: 090) messages according to the present invention. The problem that it cannot be done occurs. Therefore, a communication line for transmitting and receiving these messages may be provided separately from the BUS line 110.

  FIG. 11 is a diagram illustrating a configuration of a vehicle drive system in which a local CAN communication line 120 is provided in addition to the BUS line 110 of CAN communication. The local CAN communication line 120 shown in FIG. 11 is added in view of the above problems. That is, in the vehicle drive system of FIG. 11, the local CAN communication line 120 is provided to smoothly transmit and receive signals between the power conversion control device 210, the battery control device 410, the charger control device 510, and the converter control device 610. It has been. By doing so, there is an effect that the SOC detection error correction request (ID: 042) and the SOC detection error correction permission (ID: 090) of the present invention can be transmitted and received when necessary.

  As described above, in the configuration of the vehicle drive system in FIG. 11, the power conversion control device 210, the battery control device 410, the charger control device 510, and the converter control device 610 are different from the CAN communication BUS line 110. The communication lines 120 are connected to each other. The SOC detection error correction request message from the battery control device 410 to the power conversion control device 210 and the vehicle controller 100, and the SOC detection error correction permission message from the power conversion control device 210 to the battery control device 410 and the converter control device 610 are as follows. Are transmitted via the local CAN communication line 120.

  Next, SOC detection error correction performed by the battery control device 410 will be described. FIG. 12 is a diagram illustrating the relationship between the open-circuit voltage of the high-voltage battery 420 and the SOC. The open circuit voltage (V) and SOC (%) of the high voltage battery 420 are in a relationship as shown in FIG. Therefore, if the open circuit voltage (V) of the high voltage battery 420 is known, the SOC (%) can be obtained. For example, when the open-circuit voltage value is OCV1 shown in FIG. 12, the SOC value is calculated to be 60%.

  Here, a method in which the battery control device 410 calculates the open-circuit voltage of the high-voltage battery 420 from the detection value of the voltmeter 400V in FIG. 4 will be described.

OCV = Vdc−R1 · Idc−Vp (1)
The open circuit voltage (OCV) of the high voltage battery 420 is obtained by the above equation 1. In Equation 1, Vdc (V) is a detected value of the voltmeter 400V, R1 (Ω) is an internal resistance value of the high voltage battery 420, Idc (A) is a detected value of the ammeter 400A (in the case of discharging, the sign is minus, In the case of charging, the sign is plus), and Vp (V) represents the polarization voltage value of the high voltage battery 420, respectively.

  The internal resistance value R1 varies depending on the temperature and state of the high voltage battery 420. The polarization voltage value Vp also varies depending on the temperature and state of the high voltage battery 420. Further, the polarization voltage value Vp does not immediately become zero even when Idc = 0, but attenuates with time and becomes zero. For this reason, the data of the internal resistance value R1 and the polarization voltage value Vp for various temperatures are acquired in advance, mapped, and stored in the battery control device 410. The battery cells 420 (1) to 420 (n) are provided with one or more thermistors (not shown) so that the temperature of each battery cell can be detected. Therefore, if the detection value Vdc of the voltmeter 400V and the detection value Idc of the ammeter 400A are known, the battery control device 410 can obtain the open-circuit voltage of the high-voltage battery 420 from Equation 1 with reference to the map data. Based on this result, the SOC value can be obtained from FIG.

The battery control device 410 can obtain the SOC of the high-voltage battery 420 during charging / discharging from the following Equation 2.
SOCn (%) = kSOC (v) n + (1−k) SOC (i) n Equation 2

In Equation 2, SOC (v) n represents the SOC value obtained from the OCV in Equation 1. On the other hand, SOC (i) n represents the SOC value obtained from the integrated value of the input / output current flowing through the high voltage battery 420, and is obtained by the following equation (3).
SOC (i) n = (∫Iddcdt) / Q (3)

  In Expression 3, Idc (A) represents the detection value of the ammeter 400A (the sign is negative for discharging and the sign is positive for charging), and Q (Ah) is the high voltage battery 420, as in Expression 1. Represents the battery capacity. In addition, k is a variable. As the current input / output from the high voltage battery 420 is larger, k is smaller, and as the current is smaller, k is larger. That is, when the input / output current of the high-voltage battery 420 is large, SOC (i) n representing the integrated term of the input / output current is dominant in Equation 2, and conversely, when the input / output current is small, The represented SOC (v) n becomes dominant. Thus, in Equation 2, in order to increase the SOC detection accuracy, the SOC value obtained from the open circuit voltage and the SOC value obtained from the integration of the input / output current values of the high-voltage battery 420 are expressed as k values. It is prorated by the calculation.

  The value of the battery capacity Q in Expression 3 varies depending on the life (degradation degree) of the high voltage battery 420 and the like. Therefore, the value of the battery capacity Q for various situations is acquired in advance, mapped, and stored in the battery control device 410.

  When performing the SOC detection error correction, the battery control device 410 sets the input / output current of the high-voltage battery 420 to 0 and sets the integrated value of the input / output current so far to 0. Thereby, in the above equation 2, the value of SOC (i) n based on the integrated value of current is set to 0, and the value of SOC (v) n based on the open circuit voltage at that time is obtained as the value of initial SOC. In this way, the battery control device 410 can perform error correction with respect to the SOC of the high voltage battery 420.

In addition, regarding Formula 2, only the general idea with respect to the calculation method of SOC of the high voltage battery 420 is shown, and other calculation methods may be used. For example, the SOC of the high voltage battery 420 may be calculated by using the following expression 4 in which the second term of the expression 2 is changed and sequentially adding the differences in the dt time.
SOCn (%) = kSOC (v) n + (1−k) {SOC (i) n−1 + (Idc ′ · dt) / Q}

  FIG. 13 is a diagram showing a time change state of the SOC detection error after the IGN is turned ON. In FIG. 13, t0 represents the time of IGN ON. That is, time t0 is the timing when the driver turns on the start start switch (not shown) of the electric vehicle 1. Normally, since the SOC detection error correction is performed at the time t0, the SOC detection error once becomes zero. Thereafter, the SOC detection error gradually increases as time elapses. When the battery control device 410 transmits the SOC detection error correction request at the timing of time t1 when the predetermined time dt1 has elapsed from time t0, the SOC detection error correction is performed when the SOC detection error correction permission is subsequently received. As a result, the SOC detection error becomes zero.

  FIG. 14 is a diagram illustrating a time change state of the SOC detection error when IGN ON, IGN OFF, and IGN ON are continuously performed. In FIG. 14, t0 is the time of IGN ON, that is, the timing when the driver turns on the travel start switch (not shown) of the electric vehicle 1 as in FIG. 13. In this case as well, as in FIG. 13, the SOC detection error correction is normally performed at the time t0, so the SOC detection error once becomes zero. Thereafter, the SOC detection error gradually increases as time elapses.

  In FIG. 14, te represents the IGN OFF timing. At this time te, the electric vehicle 1 stops according to the driver's intention. Thereafter, when the travel start switch (not shown) of the electric vehicle 1 is turned on again at the time t0 ′ after the time dt has elapsed from the time te, the electric vehicle 1 is turned on similarly to the time t0. Performs SOC detection error correction and starts running. After the electric vehicle 1 starts running, the SOC detection error gradually increases.

  Here, at time t0, a sufficient time has elapsed since the driver turned off the travel start switch of the electric vehicle 1 (IGN OFF) before that, and the high voltage battery 420 has a sufficient polarization voltage Vp. Suppose that it is attenuated to zero. In this state, when the driver turns on the travel start switch of the electric vehicle 1 (IGN ON), the battery control device 410 starts an activation sequence, and the initial SOC at time t0 is detected.

Since the integrated value of the input / output current of the high voltage battery 420 is zero at the time t0, the value of Equation 3 is zero. Therefore, the value of the second term of Expression 2 is also 0, and Expression 2 is expressed as Expression 2a below.
SOCn (%) = SOC (v) n Equation 2a

Here, since Idc = 0 and Vp = 0 in the expression 1 at the time t0, the expression 1 is expressed as the following expression 1a.
OCV = Vdc ... Formula 1a

  From the equation 1a, it can be seen that if the voltage value of the high voltage battery 420 is detected as the value of Vdc from the voltmeter 400V, the value of OCV is obtained. The SOC detection error correction is performed by obtaining the initial SOCn (%) from FIG. 12 based on the OCV value. Thereafter, when the startup sequence of the battery control device 410 proceeds and the high voltage battery 420 is connected to the power conversion circuit 220 and current starts to flow, SOC detection is started based on Equation 2.

  In addition, when the driving start switch is turned ON again (IGN ON) at time t0 ′ after the time dt has elapsed since the driver turned OFF the driving start switch of the electric vehicle 1 at time te (IGN OFF), If the time dt is equal to or greater than a certain threshold value, it is considered that the polarization voltage Vp is sufficiently attenuated to become zero. In this case, the initial SOC is detected as in the case of time t0 described above.

If the time dt is less than or equal to a certain threshold value, the polarization voltage Vp is considered, and the expression 1 is expressed as the following expression 1b.
OCV = Vdc−Vp Equation 1b

  From the equation 1b, it can be seen that if the voltage value of the high voltage battery 420 is detected as the value of Vdc from the voltmeter 400V, the OCV can be calculated from the mapped polarization voltage Vp value. The SOC detection error correction is performed by obtaining the initial SOCn (%) from FIG. 12 based on the OCV value. Alternatively, the initial SOC may be set to SOCn (%) when IGN is OFF.

  FIG. 15 is a diagram illustrating an example of a detection error of the current sensor with respect to the input current. In FIG. 15, Temp1 represents an absolute value of a detection error with respect to an input (detection) current at a reference temperature (for example, 25 ° C.) in a general current sensor. Note that the absolute value here is the case where an error in the positive direction (a value larger than the true value) occurs with respect to the input (detection) current, and an error in the negative direction (a value smaller than the true value). ) May occur. The reason why the input (detection) current has plus and minus is that the direction in which the high voltage battery 420 is discharged is defined as minus, and the current in the charging direction is defined as plus. Generally, the detection error of the current sensor varies within a range lower than Temp1 indicated by a solid line in FIG.

  In FIG. 15, Temp_U represents the upper limit of the detection error of a general current sensor. For example, when the temperature of the current sensor changes from the reference temperature (25 ° C.) to 125 ° C., the detection error of the current sensor increases as Temp_U. Thus, a general current sensor has a temperature characteristic. The same applies to the ammeter 400A shown in FIG. That is, if the current sensor having an error is used as the ammeter 400A to detect the input / output current of the high voltage battery 420 and the SOC is detected based on the integrated value of the input / output current, the SOC detection error increases with time. I will do it. Note that in FIG. 15, even if the input (detection) current is zero, the absolute value of the detection error is not zero.

  FIG. 16 is a diagram illustrating an example of the detection error of the current sensor with respect to the input current after the SOC detection error correction. In FIG. 16, Temp1 'represents the absolute value of the detection error with respect to the input (detection) current in the ammeter 400A after the SOC detection error correction. FIG. 16 shows that the value of Temp1 'is zero when the input (detection) current is zero. Therefore, if the input / output current from the high voltage battery 420 is known to be zero, the battery control device 410 can offset the detection value of the ammeter 400A from Temp1 to Temp1 'as shown in FIG. Thereby, when the actual input / output current of the high voltage battery 420 is zero, the detection value of the input current by the ammeter 400A can be corrected to be zero.

  When the driver turns on the travel start switch of the electric vehicle 1 (IGN ON), the negative relay 9NS and the precharge relay 9PPS in the DC harnesses 9P and 9N are turned on (connected), so that the high voltage battery 420 and the power conversion circuit are turned on. 220 is electrically connected. Before this connection, since the input / output current of the high voltage battery 420 is zero, the battery control device 410 can correct the SOC detection error.

  In the conventional vehicle drive system, after the high voltage battery 420 and the power conversion circuit 220 are electrically connected as described above, the battery control device 410 does not know when the input / output current of the high voltage battery 420 becomes zero. . Therefore, the SOC detection error correction cannot be performed until the IGN is turned on again after the IGN is turned off by the driver's intention.

  On the other hand, in the vehicle drive system of the present embodiment, the battery control device 410 receives the SOC detection error correction permission signal transmitted from the power conversion control device 210, whereby the high voltage battery 420 and the power conversion circuit 220 are electrically connected. Even after being connected to, it is possible to know the timing when the input / output current of the high voltage battery 420 becomes zero. Therefore, it is possible to correct the detection error of the charged state of the high voltage battery 420 while the electric vehicle 1 is traveling without particularly increasing the cost.

  The embodiments and modifications described above are merely examples, and the present invention is not limited to these contents as long as the features of the invention are not impaired.

  DESCRIPTION OF SYMBOLS 1 Electric vehicle, 30 Rotating electrical machinery, 100 Vehicle controller, 110 BUS line, 200 Power converter, 210 Power conversion controller, 220 Power converter circuit, 400 Battery device, 400A Ammeter, 400V Voltmeter, 410 Battery controller, 420 High voltage battery, 500 charger, 510 charger controller, 600 DCDC converter, 610 converter controller, 700 low voltage battery

Claims (8)

A power conversion control device that is connected to a battery control device that controls charging / discharging of a battery and that controls a power conversion circuit that supplies an alternating current to a motor that drives a vehicle using a direct current supplied from the battery,
The power conversion circuit has switching elements of three-phase upper and lower arms,
When the vehicle is running , the control state of the power conversion circuit is the direct current when the three-phase short circuit in which the upper arm or the lower arm of all the switching elements are turned on or when the switching is stopped when all the switching elements are stopped. Determining that the current value of the current is zero and controlling the battery control device to give a permission signal for permitting the start of error correction for the state of charge of the battery detected by the battery control device; and sends it to the,
A power conversion control device that does not transmit the permission signal when the induced voltage of the motor is equal to or higher than a predetermined value even when the switching is stopped while the vehicle is running . The power conversion control device according to claim 1 ,
The power conversion control apparatus which transfers the control state of the said power converter circuit to the said zero current control state according to operation of the driver | operator of the said vehicle driven by the said motor. A battery control device that is connected to the power conversion control device according to claim 1 and controls charging / discharging of the battery,
Detecting the state of charge of the battery;
A battery control device that performs error correction for a state of charge of the battery when the permission signal is transmitted from the power conversion control device. The battery control device according to claim 3 , wherein
Battery control for transmitting a request signal for requesting permission to start error correction for the charged state of the battery after a predetermined time has elapsed since the battery and the power conversion circuit are connected to each other and the vehicle starts running. apparatus. The battery control device according to claim 3 or 4 ,
By calculating a first charge state value based on the voltage of the battery and a second charge state value based on an integrated value of the current flowing through the battery, the charge state of the battery is detected,
A battery control device that performs error correction for the state of charge of the battery by setting the integrated value to 0. The power conversion control device according to claim 1 or 2 ,
A drive control subsystem comprising: the battery control device according to any one of claims 3 to 5 . The drive control subsystem according to claim 6 ,
An integrated control device that integrally controls the power conversion control device and the battery control device, and the power conversion control device and the battery control device are connected via a first signal line,
The power conversion control device and the battery control device are connected via a second signal line different from the first signal line,
The drive control subsystem in which the permission signal is transmitted from the power conversion control device to the battery control device via the second signal line. The drive control subsystem according to claim 6 or 7 ,
A converter control device that controls a DCDC converter that charges the low-voltage battery by converting the DC power supplied from the battery to a voltage and outputting the voltage to the low-voltage battery;
The converter control device is a drive control subsystem that stops the operation of the DCDC converter when the permission signal is transmitted from the power conversion control device.

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