DE102016222874A1 - Electric vehicle control device - Google Patents

Abstract

An INVCM controls a forced discharge circuit to perform a forced discharge of a charge accumulated in the smoothing capacitor (step S4) when it is determined that a break element interrupts an electric current supplied from a third power storage device (step S1). when a hybrid vehicle is stopped (step S2), and controls the forced discharge circuit so that forced discharge of the charge accumulated in the smoothing capacitor is not performed when it is determined that the interruption element is the one from the third power storage device supplied power interrupts (step S1) when the hybrid vehicle is running (step S2).

Description

BACKGROUND OF THE INVENTION

1. Technical area

This invention relates to an electric vehicle control device.

2. Previous state of the art

Revealed so far JP 2001-320801 A a technique relating to a vehicle comprising: a high voltage power supply, a relay having a contact point intervening between the high voltage power supply and a power line of a vehicle, an interruption element serving as an artificial working element, an output power of the high voltage Power supply at a position near the power supply to interrupt relative to the relay, a Untersagungseinheit to prohibit a relay contact closing state when a processing operation of the interruption element is detected, a driving operation detection unit that detects a driving operation of a driver, an evaluation unit, the evaluates a detection result of the operation detection unit based on a detection result of the drive operation detection unit, and a cancellation unit that cancels the prohibition of the relay contact closure state by the prohibition unit when the evaluation unit determines mt that the detection result of the operation detection unit is not the processing operation detection of the interruption element.

A smoothing capacitor that smoothes a voltage between an inverter and a high voltage battery is provided in an electric vehicle that includes: the high voltage battery that generates a direct current, the inverter that converts the direct current generated by the high voltage battery into an alternating current converts, as well as an electric motor, which is driven by the alternating current, which is converted by means of the inverter.

When the inverter and the electric motor, which is operated at a high voltage from the high-voltage battery, are maintained or inspected by human labor in such an electric vehicle, the output power of the high-voltage battery is cut off by the interruption member, thereby ensuring safety during maintenance and inspection is ensured.

Even if the output power of the high-voltage battery is interrupted by means of the interruption element, a charge is accumulated in the smoothing capacitor. For this reason, there is a need to perform a forced discharge of the charge accumulated in the smoothing capacitor to ensure safety during maintenance and inspection.

For this reason, the prior art electric vehicle is provided with a forced discharge circuit that performs forced discharge of the charge accumulated in the smoothing capacitor. The forced discharge circuit includes a discharge resistor that converts the charge accumulated in the smoothing capacitor into heat, and a switch that switches so that a current flows to the discharge resistor or does not flow.

The switch of the forced discharge circuit is controlled by a computer unit. That is, the computer unit turns on the switch of the forced discharge circuit so that forced discharge of the charge accumulated in the smoothing capacitor is performed when the processing operation of the interruption element is performed.

In a vehicle including an electric motor and a driving wheel, which are operated in a synchronization state as an electric vehicle, there is a case where the electric motor in a driving state serves as a generator. For example, when the processing operation of the interruption element is detected in this state, the switch of the forced discharge circuit is turned on. As a result, there is a concern that excessive current generated by the electric motor serving as the generator can flow to the discharge resistance of the forced discharge circuit.

In this way there is at the in JP 2001-320801 A The prior art disclosed no consideration for a case in which the processing operation of the interruption element is detected when the vehicle is running. For this reason, there arises a problem that the discharge resistance of the forced discharge circuit can not be protected, which performs forced discharge of the charge accumulated in the smoothing capacitor, and the smoothing capacitor smoothes the voltage between the inverter and the high voltage battery.

BRIEF SUMMARY OF THE INVENTION

The present invention has been made in consideration of the circumstances described above, and its object is to provide a An electric vehicle control apparatus capable of protecting a discharge resistance of a forced discharge circuit that performs a forced discharge of a charge accumulated in a smoothing capacitor, the smoothing capacitor smoothing a voltage between an inverter and a high voltage battery.

According to aspects of this invention, there is provided an electric vehicle control apparatus for an electric vehicle equipped with a high-voltage battery that generates a direct current, an inverter that converts the direct current generated by the high-voltage battery into an alternating current, an electric motor passing through is driven by the inverter converted AC and moves in synchronization with drive wheels, a breaker that interrupts a supplied from the high-voltage battery electric current, a smoothing capacitor that smoothes a voltage between the inverter and the high-voltage battery, and a circuit for a forced discharge that performs a forced discharge of a charge accumulated in the smoothing capacitor, the electric vehicle control unit including: a control unit that controls the forced discharge circuit so that a forced discharge of a charge accumulated in the smoothing capacitor is performed when it is determined that the interruption element interrupts an electric power supplied from the high-voltage battery when the electric vehicle is stopped, and thus controls the forced discharge circuit in that no forced discharge of the charge accumulated in the smoothing capacitor is performed when it is determined that the interruption element interrupts the electric power supplied from the high-voltage battery when the electric vehicle is running.

According to the aspects of this invention, it is possible to provide an electric vehicle control apparatus capable of protecting a discharge resistance of a forced discharge circuit that performs forced discharge of a charge accumulated in a smoothing capacitor, the smoothing capacitor clamping a voltage between an inverter and a high-voltage battery smoothes.

BRIEF DESCRIPTION OF THE DRAWINGS

1 FIG. 12 is a diagram of a configuration showing a main part of a hybrid vehicle using an electric vehicle driving control apparatus according to an embodiment of this invention; FIG.

2 FIG. 12 is a diagram of a configuration showing an inverter and inverter components incorporated in FIG 1 are shown; and

3 FIG. 10 is a flowchart showing a control operation of the electric current of the electric vehicle control device according to an embodiment of this invention. FIG.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of this invention will be described with reference to the drawings. Further, a hybrid vehicle equipped with an electric vehicle control device according to embodiments of this invention will be described below.

As in 1 shown includes a hybrid vehicle 1 an engine 2 acting as an internal combustion engine, a transmission 3 , a motor generator 4 , a drive wheel 5 , a hybrid control unit (HCU) 10 that is generally the hybrid vehicle 1 controls, an engine control module (ECM) 11 that the engine 2 controls a transmission control module (TCM) 12 which is the transmission 3 controls, an integrated starter generator control module (ISGCM) 13 , an inverter control module (INVCM) 14 , a Low Voltage Battery Management System (BMS) 15 as well as a high voltage BMS 16 ,

The motor 2 is provided with a plurality of cylinders. In the embodiment, the engine is 2 configured to perform a series of four strokes including an intake stroke, a compression stroke, a power stroke, and an exhaust stroke on each cylinder.

An integrated starter generator (ISG) 20 as well as a starter 21 are with the engine 2 connected. The ISG 20 is through a belt 22 or the like with a crankshaft 18 of the motor 2 connected. The ISG 20 serves as an electric motor that drives the engine 2 starts as it is rotated by means of an electric current supplied thereto, and serves as a generator having a rotational force transmitted from the crankshaft 18 acting, converted into an electric current.

If the ISG 20 by means of the control of the ISGCM 13 when the electric motor is used, the engine becomes 2 in the embodiment, restarted from a stop condition caused by an idle stop function. If the ISG 20 As the electric motor is used, the driving operation of the hybrid vehicle 1 get supported.

The ignition 21 includes an electric motor and a gear transmission, which are not shown in the drawings. When the starter 21 the Electric motor turns, turns the crankshaft 18 rotated, so that at the time of ignition a rotational force on the engine 2 is transmitted. That way, the engine becomes 2 by means of the starter 21 started and by means of the ISG 20 Restarted from the stop state caused by the idle stop function.

The gear 3 is configured so that the drive wheels 5 by a drive shaft 23 are driven while the speed is changed by the engine 2 is delivered. The gear 3 includes a constant toothed transmission mechanism 25 which corresponds to a parallel axis gear mechanism, a clutch 26 , which corresponds to a dry clutch of the normally closed type, a differential mechanism 27 and an actuator (not shown).

The gear 3 is configured as a so-called automated manual transmission (AMT) and is used to control a speed level of the transmission mechanism 25 to switch or the clutch 26 by means of the TCM 12 controlled actuator to connect or disconnect. The differential mechanism 27 is configured to that of the transmission mechanism 25 output power to the drive shaft 23 is transmitted.

The motor generator 4 is through a power transmission mechanism 28 , such as a chain, with the differential mechanism 27 connected. The motor generator 4 serves as an electric motor.

In this way, the hybrid vehicle 1 a parallel hybrid system in which the engine 2 and the motor generator 4 are connected in parallel to each other, and it runs by means of the power that at least one of the motor 2 and the motor generator 4 is delivered.

The motor generator 4 also serves as a generator and generates an electric current when the hybrid vehicle 1 moves. In addition, the motor generator 4 with any position of a power transmission path from the engine 2 to the drive wheel 5 be connected so that force can be transferred to this, and it is not essential with the differential mechanism 27 connected.

The hybrid vehicle 1 includes a first power storage device 30 , a low-voltage power pack 32 that is a second power storage device 31 includes a high voltage power pack 34 , which is a third power storage device 33 includes, a high voltage cable 35 and a low voltage cable 36 ,

Each of the first power storage device 30 , the second power storage device 31 and the third power storage device 33 is configured as a rechargeable secondary battery. The first power storage device 30 is configured as a lead acid battery. In the second power storage device 31 it is a power storage device having a high output power and a high energy density compared to the first power storage device 30 having.

The second power storage device 31 can in one compared to the first power storage device 30 be charged short time. In the embodiment, the second power storage device is 31 configured as a lithium ion battery. In addition, the second power storage device may be 31 also act to a nickel-hydrogen storage battery.

Each of the first power storage device 30 and the second power storage device 31 is a low-voltage battery whose number of cells is set to produce an output voltage of about 12V. The third power storage device 33 is configured, for example, as a lithium-ion battery.

In the third power storage device 33 it is a high-voltage battery whose number of cells is set so that one compared to the first power storage device 30 and the second power storage device 31 high voltage is generated. A state in which the remaining capacity of the third power storage device 33 is involved by the high voltage BMS 16 managed.

The hybrid vehicle 1 is with a general load 37 and a protective target load 38 provided that serve as electrical loads. At the general load 37 and the protective target load 38 these are other electrical loads than the starter 21 and the ISG 20 ,

At the protective target load 38 It is an electrical load that normally requires the stable supply of electrical power. The protective target load 38 includes a stability control device 38A that is a skid of the hybrid vehicle 1 prevents a control device 38B for an electric steering, which electrically supports a steering wheel operating force, and a headlight 38C , In addition, the protection target load includes 38 also lamps and instruments of an instrument panel (not shown) as well as a vehicle navigation system (not shown).

At the general load 37 it is an electrical load that is used temporarily and which is the stable supply of an electric current compared to the protective target load 38 not required. The general burden 37 For example, a windshield wiper (not shown) and an electric cooling fan that supplies cool air to the engine 2 blows.

The low voltage power pack 32 includes switch 40 and 41 in addition to the second power storage device 31 , The first power storage device 30 and the second power storage device 31 are with the starter 21 and the ISG 20 as well as with the general load 37 and the protective target load 38 connected by the low voltage cable 36 serve as the electrical load, so that it can be supplied with an electric current. The first power storage device 30 and the second power storage device 31 are with the protection target load 38 electrically connected in parallel.

The desk 40 is in the low voltage cable 36 between the second power storage device 31 and the protective target load 38 provided. The desk 41 is in the low voltage cable 36 between the first power storage device 30 and the protective target load 38 provided.

The low voltage BMS 15 controls the opening / closing states of the switches 40 and 41 such that the second power storage device 31 loaded and unloaded and the protection target load 38 an electric current is supplied. If the low voltage BMS 15 the switch 40 closes and the switch 41 opens when the engine 2 is stopped by the idle stop, the protection target load 38 an electric current from the second power storage device 31 fed, which has a high output power and a high energy density.

If the low voltage BMS 15 the switch 40 closes and the switch 41 opens when the engine 2 through the starter 21 is started and the engine 2 , which was stopped by the idle-stop control, by means of the ISG 20 Restart will be the starter 21 or the ISG 20 an electric current from the first power storage device 30 fed. In a state in which the switch 40 is closed and the switch 41 open, becomes the general load 37 also an electric current from the first power storage device 30 fed.

In this way, the first power storage device performs 30 at least the starter 21 and the ISG 20 acting as a starting device for starting the engine 2 serve an electric current too. The second power storage device 31 is configured to be at least the general load 37 and the protective target load 38 supplies an electric current.

The second power storage device 31 is both with the general load 37 as well as the protective target load 38 connected so that an electric current can be supplied to them, the switch 40 and 41 However, the low-voltage BMS 15 controlled so that preferably the protective target load 38 which normally requires the stable supply of an electric current, an electric current is supplied.

The low voltage BMS 15 controls the switches 40 and 41 in a manner different from the example described above, so that the stable operation of the protective target load 38 taking into account the operating requirement for the general load 37 and the protective target load 38 and the state of charge (the remaining charge amount) for the first power storage device 30 and the second power storage device 31 is prioritized.

The high voltage power pack 34 includes an inverter 45 in addition to the third power storage device 33 , The high voltage power pack 34 is through the high voltage cable 35 with the motor generator 4 connected, so that this an electric current can be supplied.

By controlling the INVCM 14 is the inverter 45 configured to connect an AC to the high voltage cable 35 is applied, and a direct current, which connects to the third power storage device 33 is created. If the motor generator 4 For example, performing a power running operation causes the INVCM 14 that the inverter 45 the DC, which the third power storage device 33 is removed, converted into an alternating current and the alternating current to the motor-generator 4 supplies.

If the motor generator 4 performs a regeneration operation causes the INVCM 14 that the inverter 45 the alternating current coming from the motor generator 4 is generated, converted into a direct current and the direct current of the third power storage device 33 supplies.

Every one of the HCU 10 , the ECM 11 , the TCM 12 , the ISGCM 13 , the INVCM 14 , the low voltage BMS 15 and the high voltage BMS 16 is configured as a computer unit that includes a central processing unit (CPU), a random access memory (RAM), a read-only memory (ROM), a flash memory that stores back-up data, an input port, and an output port.

The computer unit ROM, together with various constants or various maps, stores a program to the computer unit as the HCU 10 , the ECM 11 , the TCM 12 , the ISGCM 13 , the INVCM 14 , the low voltage BMS 15 and the high-voltage BMS 16 to operate.

That is, when the CPU executes the program stored in the ROM by using the RAM as a work area, the computer unit serves as any of the HCU 10 , the ECM 11 , the TCM 12 , the ISGCM 13 , the INVCM 14 , the low voltage BMS 15 and the high voltage BMS 16 the embodiment.

In the embodiment, the ECM 11 configured to perform idle-stop control. In idle-stop control, the ECM stops 11 the engine 2 when a predetermined stop condition occurs, and starts the engine 2 new by the ISG 20 through the ISGCM 13 is driven when a predetermined restart condition occurs. For this reason, the unnecessary idling of the engine 2 prevents, and thus can reduce the fuel efficiency of the hybrid vehicle 1 be improved.

The hybrid vehicle 1 is with CAN communication lines 48 and 49 provided based on a standard, such as a Controller Area Network (CAN), a local area network (LAN) in the vehicle.

The HCU 10 is through the CAN communication line 48 with the INVCM 14 and the high voltage BMS 16 connected. The HCU 10 , the INVCM 14 and the high-voltage BMS 16 send and receive a signal, such as a control signal, through the CAN communication line 48 ,

The HCU 10 is through the CAN communication line 49 with the ECM 11 , the TCM 12 , the ISGCM 13 and the low voltage BMS 15 connected. The HCU 10 , the EMC 11 , the TCM 12 , the ISGCM 13 and the low voltage BMS 15 send and receive a signal, such as a control signal, through the CAN communication line 49 ,

As in 2 shown includes the hybrid vehicle 1 main relay 50a and 50b , each in a positive electrode P and a negative electrode N of the third power storage device 33 are provided, which serves as a battery. An end to the main relay 50a is connected to the negative electrode N of the third power storage device 33 and the other end thereof is connected to a negative electrode line NL.

By controlling the INVCM 14 represents the main relay 50a a connection with the negative electrode line NL and the negative electrode N of the third power storage device 33 or separate them. An end to the main relay 50b is connected to the positive electrode P of the third power storage device 33 and the other end thereof is connected to a positive electrode line PL. By controlling the INVCM 14 represents the main relay 50b a connection with the positive electrode line PL and the positive electrode P of the third power storage device 33 or separate them.

In the embodiment, the motor generator 4 is configured as a three-phase AC motor that is driven by a three-phase (U-phase, V-phase and W-phase) AC power. The motor generator 4 For example, a stator that forms a rotating magnetic field and a rotor that is disposed in the stator and has a plurality of permanent magnets embedded therein.

The stator includes a stator core and three-phase (U-phase, V-phase, W-phase) coils wound around the stator core. When the three-phase alternating current is supplied to the three-phase coils of the stator in this case, a rotational magnetic field is formed by means of the stator. Then, when the permanent magnets embedded in the rotor are pulled toward the rotating magnetic field, the rotor is rotated. By the rotational driving force of the rotor becomes the hybrid vehicle 1 driven. This is how the motor generator works 4 as an electric motor.

Further, when the permanent magnets embedded in the rotor rotate, a rotational magnetic field is formed. Then, when an induction current flows to the three-phase coils of the stator by means of the rotational magnetic field, an electric current is generated at both ends of the three-phase coils. This is how the motor generator works 3 also as a generator.

The hybrid vehicle 1 includes a break element 51 that cuts off the electric power coming from the third power storage device 33 is supplied, a smoothing capacitor 53 that creates a voltage between the inverter 45 and the third power storage device 33 smoothes, a discharge resistance 54 , one in the smoothing capacitor 53 accumulates accumulated charge in a normal manner, as well as a circuit 55 for a forced discharge, which involves a forced discharge in the smoothing capacitor 53 accumulated charge.

In the embodiment, the interruption element is 51 configured as a high-voltage interlock (HVIL) element, which is a service connector 51a which forms an electrical path for the electric current generated by the third power storage device 33 is supplied. If then the service plug 51a is pulled out, the electric power is interrupted, that of the third power storage device 33 is supplied.

The interruption element 51 is with a monitoring line 51b provided that enters a connection state when the service connector 51a is plugged into this, or enters an interruption state when the service plug 51a is pulled out of this. Both ends of the monitoring line 51b are with the INVCM 14 connected.

The INVCM 14 is configured to determine if the service connector 51a is plugged in response to a condition in which a signal is sent to one end of the monitoring line 51b is delivered to the other end of the monitoring line 51b is entered.

In the embodiment, the service plug is 51a for example, on the cover of the high voltage power pack 34 attached. Thus, if the cover of the high-voltage power pack 34 is opened, the service plug 51a pulled out.

One end of the smoothing capacitor 53 is connected to the positive electrode line PL, and the other end thereof is connected to the negative electrode line NL. The smoothing capacitor 53 is configured to smooth a voltage of a direct current generated between the positive electrode line PL and the negative electrode line NL.

One end of the discharge resistor 54 is connected to the positive electrode line PL, and the other end thereof is connected to the negative electrode line NL. The discharge resistance 54 is provided to discharge one in the smoothing capacitor 53 accumulated charge, and is configured such that a residual voltage and a transient recovery voltage of the smoothing capacitor 53 be prevented.

The circuit 55 for a forced discharge involves a discharge resistor 56 that discharges one in the smoothing capacitor 53 accumulated charge by means of thermal conversion, and a switch 57 by the INVCM 14 is switched and causes a current to the discharge resistor 56 flows or does not flow.

The inverter 45 forms a circuit for converting an electric current, which is a direct current, of which a voltage by means of the smoothing capacitor 53 is smoothed, converted into an alternating current. The inverter 45 includes switching elements Q3 to Q8 and diodes D3 to D8. Each of the switching elements Q3 to Q8 is configured as an insulated gate bipolar transistor (IGBT).

In the switching element Q3, a collector is connected to the positive electrode line PL, and an emitter is connected to the U-phase input terminal of the motor generator 4 connected, and a gate is with the INVCM 14 connected. In the switching element Q4, a collector is connected to the emitter of the switching element Q3, an emitter is connected to the negative electrode line NL, and a gate is connected to the INVCM 14 connected.

In the diode D3, a cathode is connected to the collector of the switching element Q3, and an anode is connected to the emitter of the switching element Q3. That is, the diode D3 and the switching element Q3 constitute an upper U-phase arm.

In the diode D4, a cathode is connected to the collector of the switching element Q4, and an anode is connected to the emitter of the switching element Q4. That is, the diode D4 and the switching element Q4 form a lower U-phase arm.

In the switching element Q5, a collector is connected to the positive electrode line PL, and an emitter is connected to the V-phase input terminal of the motor generator 4 connected, and a gate is with the INVCM 14 connected. In the switching element Q6, a collector is connected to the emitter of the switching element Q5, an emitter is connected to the negative electrode line NL, and a gate is connected to the INVCM 14 connected.

In the diode D5, a cathode is connected to the collector of the switching element Q5, and an anode is connected to the emitter of the switching element Q5. That is, the diode D5 and the switching element Q5 constitute an upper V-phase arm.

In the diode D6, a cathode is connected to the collector of the switching element Q6, and an anode is connected to the emitter of the switching element Q6. That is, the diode D6 and the switching element Q6 form a lower V-phase arm.

In the switching element Q7, a collector is connected to the positive electrode line PL, and an emitter is connected to the W-phase input terminal of the motor generator 4 connected, and a gate is with the INVCM 14 connected. In the switching element Q8, a collector is connected to the emitter of the switching element Q7, an emitter is connected to the negative electrode line NL, and a gate is connected to the INVCM 14 connected.

In the diode D7, a cathode is connected to the collector of the switching element Q7, and an anode is connected to the emitter of the switching element Q7. That is, the diode D7 and the switching element Q7 constitute a top W-phase arm.

In the diode D8, a cathode is connected to the collector of the switching element Q8, and an anode is connected to the emitter of the switching element Q8. That is, the diode D8 and the switching element Q8 form a lower W-phase arm.

The gates of the switching elements Q3 to Q8 are controlled by means of a control signal, of which a duty ratio by means of the INVCM 14 is controlled so that an alternating current is present, in which the directions and the amounts of the currents, to the U, the V and the W phase of the motor-generator 4 flow, continuously changing with a phase difference of 120 °. As a result the stator of the motor-generator forms 4 the rotating magnetic field, and the rotor of the motor-generator 4 is turned.

If the INVCM 14 in the embodiment determines that the interruption element 51 that of the third power storage device 33 supplied electric power interrupts when the hybrid vehicle 1 is stopped, controls the INVCM 14 the circuit 55 for a forced discharge, to cause a forced discharge in the smoothing capacitor 53 accumulated charge is carried out. In this way, the INVCM serves 14 as a control unit 60 which the circuit 55 controls for a forced discharge.

A vehicle speed sensor 59 that detects a vehicle speed is, for example, with the INVCM 14 connected. The INVCM 14 is configured to be based on the detection result of the vehicle speed sensor 59 It determines if the hybrid vehicle 1 is stopped.

The INVCM 14 prevents the driving of the motor-generator 4 by the main relay 50a and 50b be turned off when it is determined that the interruption element 51 that of the third power storage device 33 supplied electric power interrupts when the hybrid vehicle 1 is stopped. If at this time the engine 2 driven, controls the INVCM 14 the ECM 11 to the engine 2 stop, and turn off the scaler 57 one, so that by means of the circuit 55 for forced discharge, forced discharge of one in the smoothing capacitor 53 accumulated charge is carried out.

The INVCM 14 controls the circuit 55 for a forced discharge so that a forced discharge one in the smoothing capacitor 53 accumulated charge is not performed when it is determined that the interruption element 51 that of the third power storage device 33 supplied electric power interrupts when the hybrid vehicle 1 moves.

For example, if it is determined that the interrupt element 51 that of the third power storage device 33 supplied electric power interrupts when the hybrid vehicle 1 drives, allows the INVCM 14 driving the motor-generator 4 by the main relay 50a and 50b in an ON state, and controls the ECM 11 so that driving the engine 2 is possible. This will be the switch 57 held in an OFF state, so that no forced discharge of a in the smoothing capacitor 53 accumulated charge by means of the circuit 55 for a forced discharge.

An electric current control operation of the electric vehicle control device according to embodiments of this invention having the configuration described above will be described with reference to FIG 3 described. Moreover, the electric current control operation described below is repeated while the INVCM 14 is operated.

First, the INVCM determines 14 in step S1 of 3 whether the interruption element 51 disconnects the electric power coming from the third power storage device 33 is supplied. If it is determined that the interruption element 51 does not interrupt the electric current coming from the third power storage device 33 is supplied, the INVCM terminates 14 the control operation for the electric current. If it is determined that the interruption element 51 disconnects the electric power coming from the third power storage device 33 is fed, leads the INVCM 14 the control operation for the electric current in step S2.

In step S2, the INVCM determines 14 whether the hybrid vehicle 1 is stopped. If it is determined that the hybrid vehicle 1 stopped, the INVCM performs 14 the electric power control operation in step S3. If it is determined that the hybrid vehicle 1 is not stopped, leads the INVCM 14 the electric power control operation in step S5.

In step S3, the INVCM prohibits 14 driving the hybrid vehicle 1 , The INVCM 14 prohibits the driving of the motor-generator 4 for example, by switching off the main relay 50a and 50b , If the engine 2 driven at this time, controls the INVCM 14 the ECM 11 so that the engine 2 is stopped. After the process is performed in step S3, the INVCM performs 14 the control operation for the electric current in step S4.

In step S4, the INVCM turns 14 the switch 57 one, so that by means of the circuit 55 for forced discharge, forced discharge of one in the smoothing capacitor 53 accumulated charge is carried out. After performing the process in step S4, the INVCM terminates 14 the control operation for the electric current.

In step S5, the INVCM enables 14 driving the hybrid vehicle 1 , The main relay 50a and 50b are held in an ON state, for example, to drive the motor-generator 4 to enable, and the ECM 11 is controlled so that driving the engine 2 is possible. After performing the process in step S5, the INVCM ends 14 the control operation for the electric current.

If it is determined that the interruption element 51 that of the third power storage device 33 supplied electric power interrupts when the hybrid vehicle 1 is stopped, as described above in the embodiment, the circuit 55 for forced discharge so as to perform a forced discharge of a charge accumulated in the smoothing capacitor. If, however, it is determined that the interruption element 51 that of the third power storage device 33 supplied electric power interrupts when the hybrid vehicle 1 drives, the circuit is 55 for a forced discharge so controlled that a forced discharge one in the smoothing capacitor 53 accumulated charge is not carried out.

Since it is thus possible in the embodiment, by means of the electric current generated by the motor-generator 4 is generated when the hybrid vehicle 1 drives to prevent excessive current leading to the circuit 55 For a forced discharge, it is possible to increase the discharge resistance 56 the circuit 55 to protect for a forced discharge.

Although embodiments of this invention have been described, it will be apparent to those skilled in the art that changes may be made without departing from the scope of this invention. Any and all such modifications and equivalents are intended to be included in the accompanying claims.

LIST OF REFERENCE NUMBERS

1

Hybrid vehicle (electric vehicle)

4

Motor generator (electric motor)

33

Power Storage Device (High Voltage Battery)

45

inverter

51

interruption element

53

smoothing capacitor

55

Circuit for a forced discharge

56

discharge resistor

60

control unit

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2001-320801 A [0002, 0009]

Claims (1)

An electric vehicle control apparatus for an electric vehicle equipped with a high-voltage battery that generates a direct current, an inverter that converts the direct current generated by the high-voltage battery into an alternating current, an electric motor that is driven by the direct current converted by the inverter is generated and a movement with respect to drive wheels, a breaker that interrupts a supplied from the high voltage battery electric current, a smoothing capacitor that smoothes a voltage between the inverter and the high voltage battery, and a circuit for a forced discharge, the performs a forced discharge of a charge accumulated in the smoothing capacitor, the electric vehicle control device comprising: a control unit that controls the forced discharge circuit to perform a forced discharge of a charge accumulated in the smoothing capacitor when it is determined that the interruption element interrupts an electric current supplied from the high-voltage battery when the electric vehicle is stopped; and which controls the forced discharge circuit so that forced discharge of the charge accumulated in the smoothing capacitor is not performed when it is determined that the interruption element interrupts the electric current supplied from the high-voltage battery when the electric vehicle is running.

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