JP6406143B2 - Rotating electric machine for vehicles - Google Patents

Description

  The present invention relates to a vehicular rotating electrical machine having a power generation function.

  A vehicular rotating electrical machine having a power generation function supplies power to various electric loads and batteries via wiring connected to an output terminal. During the power generation operation of the vehicular rotating electrical machine, if the wiring is disconnected from the output terminal or the battery terminal, a transient high voltage called a load dump is generated. When such a load dump occurs, load dump protection technology has been proposed in which the switching element is turned on and off to suppress a high voltage until the energy accumulated in the stator windings disappears.

  For example, in the rotating electrical machine for a vehicle described in Patent Document 1, the time during which the output voltage decreases from the first threshold voltage to the second threshold voltage immediately after the start of the load dump protection operation, and the second threshold voltage to the first threshold voltage. The time to rise up to is actually measured. In the above-mentioned vehicular rotating electrical machine, the load dump protection operation is performed regardless of the load remaining in the wiring when the load dump occurs by shortening the on / off time of the subsequent switching element from the actually measured time. The output voltage fluctuation is reduced. Further, in the above-described vehicular rotating electrical machine, when the energy accumulated in the stator windings disappears, the load dump protection is terminated and the normal rectifying operation is resumed.

Japanese Patent Laying-Open No. 2015-65788

  Generally, a vehicular rotating electrical machine performs start-up gradual excitation that gradually increases a power generation amount in order to gradually increase an engine load at the time of start-up. If start-up gradual excitation is performed after the end of load dump protection due to the occurrence of load dump, the power consumption of the load may be greater than the generated power, and the output voltage of the vehicular rotating electrical machine may decrease. . When the output voltage decreases, the power source of the power generation control device or the like cannot be maintained, and power generation may stop.

  In view of the above circumstances, it is a primary object of the present invention to provide a vehicular rotating electrical machine that can suppress the implementation of gradual excitation after the end of a load dump protection operation.

  A first aspect of the present invention is a vehicular rotating electrical machine in which a rotating shaft is connected to a rotating shaft of an internal combustion engine, and a field winding for magnetizing a field pole of a rotor and an alternating current by a rotating magnetic field generated by the field pole. A bridge circuit having a plurality of armature windings for generating a voltage, an upper arm and a lower arm, and at least one of the upper arm and the lower arm is constituted by a switching element, the armature winding A rectifier circuit that rectifies and outputs an induced voltage of the power supply, a power generation control device that controls an output voltage of the rectifier circuit by adjusting an excitation current supplied to the field winding, and controls on / off of the switching element A switching control device, wherein the power generation control device detects reset of the power generation control device or start of the internal combustion engine, and when the rotational speed of the rotor is lower than a predetermined rotational speed, A gradual excitation unit that performs gradual excitation for gradually increasing the power generation amount during a fixed gradual excitation period, and the switching control device includes a detection unit that detects the occurrence of a load dump when the output voltage exceeds a first threshold value. When the output voltage exceeds the first threshold, the switching element of one of the upper arm and the lower arm is turned on, and the output voltage reaches a second threshold lower than the first threshold. In the case of a decrease, when the generation of the load dump is detected by the protection unit that turns off the one switching element and the detection unit, a pseudo signal having a rotational speed higher than the predetermined rotational speed is generated. And a pseudo signal unit for outputting to the control device.

  According to the first invention, when the reset of the power generation control device or the start between the internal combustion engines is detected and the rotation speed of the rotor is lower than the predetermined rotation speed, the gradual excitation is performed for a predetermined gradual excitation period. . Thereby, the rotational speed of the engine can be stabilized. In addition, when the output voltage exceeds the first threshold, occurrence of a load dump is detected. When the output voltage exceeds the first threshold value, one of the switching elements of the upper arm and the lower arm is turned on, and when the output voltage drops to the second threshold value, the switching element is turned off. . That is, the load dump protection operation is performed. Thereby, it is possible to suppress the output voltage while suppressing the output voltage from being excessively lowered and re-exciting the field winding.

  Here, due to the occurrence of the load dump, the power generation control device may be reset and the start of the internal combustion engine may be erroneously detected. In this case, if the rotational speed of the rotor is lower than the predetermined rotational speed at the end of the load dump protection operation, the slow excitation may be performed even when the internal combustion engine is not started. In this regard, when occurrence of a load dump is detected, a pseudo signal having a rotational speed higher than a predetermined rotational speed is output to the power generation control device. Thereby, at the end of the load dump protection operation, even when the actual rotational speed is lower than the predetermined rotational speed, it is recognized as a rotational speed higher than the predetermined rotational speed. Therefore, when the load dump protection operation is finished and the power generation is restarted, it is possible to suppress the gradual excitation.

  According to a second aspect of the present invention, the power generation control device detects a cancellation unit that cancels the gradual excitation when the output voltage becomes lower than a predetermined voltage, and reset of the power generation control device or start of the internal combustion engine. An invalidation unit that invalidates cancellation of the gradual excitation by the cancellation unit for a predetermined period of time, and the pseudo signal unit outputs the pseudo signal until the cancel function by the cancellation unit is enabled. It transmits to a power generation control apparatus, It is characterized by the above-mentioned.

  According to the second aspect of the present invention, since the reset of the power generation control device or the start of the internal combustion engine is detected and until the predetermined period elapses, the gradual excitation is not stopped even if the output voltage becomes lower than the predetermined voltage. The engine can be reliably started in a low load state. However, when the occurrence of a load dump is detected, a pseudo signal is output until the cancel function is enabled. Therefore, even when the power generation control device is reset due to the occurrence of the load dump and the start of the internal combustion engine is erroneously detected, it is possible to suppress the slow excitation after the load dump protection operation is completed. In addition, after the gradual excitation cancel function is enabled, the gradual excitation is stopped if the output voltage falls below the predetermined voltage, so that the output voltage does not fall below the predetermined voltage. Therefore, a decrease in output voltage can be suppressed, and power generation can be stopped.

  In a third aspect of the invention, the power generation control device includes a speed detection terminal that detects a rotation speed of the rotor, the switching control device includes a signal output terminal that outputs the pseudo signal, and the speed detection terminal is The armature winding is connected to one end of the armature winding via a resistor and to the signal output terminal.

  According to the third invention, a signal obtained by superimposing a pseudo signal on the phase voltage of the armature winding is input to the speed detection terminal of the power generation control device. Thereby, the power generation control device can detect the rotational speed higher than the predetermined rotational speed by reading the pseudo signal. In addition, since the phase voltage is input to the speed detection terminal via the resistor, the power generation control device continues the power generation control by detecting the phase voltage even when some element of the switching control device fails. be able to.

  According to a fourth aspect of the present invention, the switching control device includes a first path that outputs a phase voltage of the armature winding, and a second path that outputs the pseudo signal, and the pseudo signal unit is configured to detect the detection signal. When the occurrence of the load dump is detected by the unit, the connection between the first path and the power generation control device is disconnected and the second path and the power generation control device are connected. .

  According to the fourth invention, when the load dump occurs, the connection between the first path and the power generation control device is disconnected, and the second path and the power generation control device are connected. Instead, a pseudo signal is input. In this case, since the pseudo signal is directly input to the power generation control, the pseudo signal having an ideal waveform is read. Therefore, erroneous detection of the rotation speed can be suppressed. Further, it is not necessary to connect a resistor between the armature winding and the power generation control device. In general, when a resistor is connected outside the module, processing such as welding and waterproofing is required, and the manufacturing cost increases. In this respect, since there is no need to connect a resistor between the armature winding and the power generation control device, that is, outside the module, it is possible to reduce the labor and manufacturing cost during manufacturing.

The figure which shows the structure of the generator for vehicles which concerns on 1st Embodiment. The figure which shows the structure of the electric power generation control apparatus which concerns on 1st Embodiment. The figure which shows the structure of the rectifier module which concerns on 1st Embodiment. The figure which shows generation | occurrence | production of the negative surge at the time of load interruption | blocking. (A) Output voltage, output-end capacitor voltage and phase voltage, (b) Lower switch drive signal, and (c) Regulator voltage time chart at the time of conventional load interruption. The time chart of (a) output voltage, output terminal capacitor voltage, and phase voltage, (b) driving signal of lower switch, (c) pseudo signal, and (d) regulator voltage at the time of load interruption of the first embodiment. The figure which shows the structure of the signal output part which concerns on 1st Embodiment. The figure which shows (a) phase voltage and (b) pseudo | simulation signal. The figure which shows the signal input into a power generation control apparatus in 1st Embodiment. The flowchart which shows the process sequence of load dump protection operation | movement. The figure which shows the structure of the signal output part which concerns on 2nd Embodiment. The figure which shows the signal input into a power generation control apparatus in 2nd Embodiment.

  Hereinafter, embodiments embodying a rotating electrical machine for a vehicle will be described with reference to the drawings. The vehicular rotating electrical machine according to the present embodiment is assumed to be embodied as a vehicular generator.

(First embodiment)
First, the configuration of the vehicular generator according to the present embodiment will be described with reference to FIG. The vehicle generator 10 according to the present embodiment includes two armature windings 11 and 12, a field winding 14, two rectifier module groups 15 and 16, a power generation control device 17, and a Zener diode 18. Yes.

  The armature winding 11 is a multi-phase stator winding, specifically, a three-phase winding composed of an X-phase winding, a Y-phase winding, and a Z-phase winding, and a stator core (not shown). It is wound. Similarly, the armature winding 12 is a three-phase stator winding composed of a U-phase winding, a V-phase winding, and a W-phase winding. The armature winding 12 is wound at a position shifted from the armature winding 11 by an electrical angle of 30 degrees. In the present embodiment, the stator is constituted by the armature windings 11 and 12 and the stator core.

  The field winding 14 is wound around a field pole (not shown) arranged opposite to the inner peripheral side of the stator core to constitute a rotor. The rotating shaft 140 of the rotor is connected to the engine 200 (internal combustion engine) via a pulley or the like. By passing an excitation current through the field winding 14, the field pole is magnetized. An AC voltage is generated in the armature windings 11 and 12 by the rotating magnetic field generated by the magnetized field pole.

  The rectifier module group 15 includes rectifier modules 15X, 15Y, and 15Z. Each of the rectifier modules 15X, 15Y, and 15Z includes a series body of two MOS transistors and a control circuit 54 that controls on / off of the two MOS transistors. The rectifier modules 15X, 15Y, and 15Z are connected to the X-phase winding, Y-phase winding, and Z-phase winding of the armature winding 11, respectively. As shown in FIG. 4, the rectifier module 15X, 15Y, 15Z is a three-phase bridge circuit having an upper arm and a lower arm, and induction generated in the armature windings 11, 12 A rectifier circuit 15A for rectifying the voltage is configured. This rectifier circuit 15A rectifies the AC voltage output from the armature winding 11 and outputs it from the B terminal which is an output terminal. The detailed configuration of the rectifier module 15X will be described later.

  Similarly, the rectifier module group 16 includes rectifier modules 16U, 16V, and 16W connected to the U-phase winding, the V-phase winding, and the W-phase winding of the armature winding 12. The six MOS transistors included in the rectifier modules 16U, 16V, and 16W form a rectifier circuit (not shown) that is a three-phase bridge circuit having an upper arm and a lower arm. This rectifier circuit rectifies the AC voltage output from the armature winding 12 and outputs it from the output terminal B.

  The power generation control device 17 is connected via the F terminal based on a comparison between the output voltage Vb of the vehicle generator 10 (the output voltage of the rectifier circuit included in the rectifier module groups 15 and 16) and the adjustment voltage Vref. The exciting current supplied to the field winding 14 is controlled. That is, the power generation control device 17 adjusts the excitation current so that the output voltage Vb becomes the adjustment voltage Vref. The detailed configuration of the power generation control device 17 will be described later.

  The Zener diode 18 is connected between the output terminals of the rectifier module groups 15 and 16, that is, between the B terminal and the E terminal connected to the ground. Specifically, the cathode of the Zener diode 18 is connected to the B terminal, and the anode is connected to the E terminal.

  One end of the wiring 25 is connected to the B terminal which is an output terminal of the vehicle generator 10. The other end of the wiring 25 is connected to the positive terminal of the battery 40. That is, the wiring 25 is an electrical wiring that connects the B terminal and the positive terminal of the battery 40. The wiring 25 is connected to the output end capacitor 20 and the first end of the load 31. Further, the first end of the load 32 is connected to the positive terminal of the battery 40 by a wire different from the wire 25. The loads 31 and 32 are in-vehicle electric loads such as wipers, air conditioners, headlights, various ICs, and ECUs. The negative terminal of the battery 40, the output end capacitor 20, and the second ends of the loads 31 and 32 are connected to the ground. The output voltage Vb of the vehicular generator 10 is supplied to the battery 40 and the loads 31 and 32 via the wiring 25 and other wirings.

  Next, the power generation control device 17 will be described with reference to FIG. The power generation control device 17 includes an N-channel MOSFET switching element 71, freewheeling diode 72, resistors 73 and 74, a voltage comparison circuit 75, an excitation current control circuit 76, a rotation detection circuit 77, a communication circuit 78, a power supply circuit 79, and a capacitor. 80. The power generation control device 17 includes a B terminal (output terminal), an F terminal (excitation drive terminal), a P terminal (phase voltage detection terminal), and an L terminal (communication terminal).

  The power supply circuit 79 supplies operating power to each circuit included in the power generation control device 17 using the voltage at the B terminal. The communication circuit 78 performs serial communication with the ECU 100, which is an external control device, via the L terminal, and receives the adjustment voltage Vref and the like transmitted from the ECU 100.

  When the output voltage Vb of the vehicular generator 10 suddenly drops due to the occurrence of a load dump, which will be described later, that is, when the voltage at the B terminal drops rapidly, When the capacity is relatively small, when the output voltage Vb drops, the power supply voltage becomes insufficient and the power generation control device 17 is automatically reset. Further, the power generation control device 17 is reset when the output voltage Vb suddenly drops as the engine 200 is started or when it is determined that the engine 200 is started.

  The switching element 71 and the free wheeling diode 72 are connected between the B terminal and the F terminal, and the F terminal and the E terminal, respectively. The resistors 73 and 74 are connected in series between the B terminal and the E terminal to constitute a voltage dividing circuit, and a voltage obtained by dividing the output voltage Vb is input to the voltage comparison circuit 75. The voltage comparison circuit 75 compares the divided output voltage Vb with a reference voltage corresponding to the adjustment voltage Vref.

  The excitation current control circuit 76 adjusts the excitation current supplied to the field winding 14 by controlling on / off of the switching element 71 based on the comparison result of the voltage comparison circuit 75. Specifically, the excitation current control circuit 76 stops or reduces the supply of the excitation current when the output voltage Vb is higher than the adjustment voltage Vref, and the excitation current control circuit 76 when the output voltage Vb is equal to or less than the adjustment voltage Vref. Supply. When the rotation detection circuit 77 detects the rotation stop of the rotor, the excitation current control circuit 76 stops or reduces the supply of the excitation current and shifts to the initial excitation state.

  In general, the vehicular generator performs gradual excitation by gradually increasing the excitation current and gradually increasing the power generation amount when starting the engine 200 while the vehicle is stopped. If the amount of power generation is suddenly increased when the engine 200 is started, the load on the engine 200 will increase rapidly. As a result, the rotational speed of the engine 200 decreases, and the engine 200 starts unstable. Therefore, in general, the vehicular generator performs gradual excitation so that the load of engine 200 is gradually increased when engine 200 is started.

  In the present embodiment, the exciting current control circuit 76 includes functions of a gradual excitation unit 76a, a canceling unit 76b, and a disabling unit 76c. The gradual excitation unit 76a detects a reset of the power generation control device 17, and when the rotational speed of the rotor of the vehicle generator 10 is lower than the gradual excitation cancellation rotational speed (predetermined rotational speed), a predetermined gradual excitation period (for example, , A few s), and implement slow excitation. Alternatively, the gradual excitation unit 76a detects the start of the engine 200 and performs gradual excitation for a predetermined de-excitation period when the rotational speed of the vehicle generator 10 is lower than the gradual excitation canceling rotational speed. The gradual excitation unit 76a receives a power generation start instruction from the ECU 100, and detects the start of the engine 200 when the rotational speed is detected or when the power generation control device 17 is reset. Therefore, when the power generation control device 17 is reset due to the occurrence of the load dump, if the rotational speed of the vehicular generator 10 is lower than the slow excitation canceling rotational speed, the slow excitation is performed.

  The cancel unit 76b cancels the gradual excitation when the output voltage Vb becomes lower than a predetermined voltage. In general, when the output voltage Vb is lower than a predetermined voltage, if the gradual excitation is continued, the output voltage Vb is excessively lowered. If the output voltage Vb is excessively reduced, the power sources of various ICs and ECUs are insufficient, and the various ICs and ECUs are stopped. Accordingly, the cancel unit 76b cancels the gradual excitation when the output voltage Vb becomes lower than the predetermined voltage.

  The invalidation unit 76c invalidates the cancellation of the slow excitation by the cancellation unit 76b for a predetermined period (for example, several hundred ms) after the reset of the power generation control device 17 or the start of the engine 200 is detected. Thereby, even if the output voltage Vb becomes lower than the predetermined voltage after the reset of the power generation control device 17 or the start of the engine 200 is detected until the predetermined period elapses, the gradual excitation is continued. That is, until the predetermined period elapses, the engine 200 is prioritized over the maintenance of the output voltage Vb, and the rapid increase in the load is reliably suppressed. Thereby, engine 200 can be started stably.

  The rotation detection circuit 77 is connected to the P terminal, and the P terminal is connected to the armature windings 11 and 12 (for example, X-phase windings) via the resistor 13. The rotation detection circuit 77 receives the phase voltage Vp (for example, X phase) of one of the armature windings 11 and 12 via the resistor 13 (shown by a broken line) and the P terminal. The rotation detection circuit 77 detects the rotation speed of the rotor based on the oscillation cycle of the amplitude of the input phase voltage Vp. Further, during the load dump protection operation, the rotation detection circuit 77 receives a pseudo signal Sp from a signal output unit 60 of the rectifier module 15X described later, and detects the rotation speed of the rotor based on the received pseudo signal Sp. . In the present embodiment, the P terminal corresponds to the speed detection terminal.

  The capacitor 80 is connected between the B terminal and the E terminal, and removes noise input from the B terminal which is an output terminal of the rectifier module groups 15 and 16. The capacitance Cin of the capacitor 80 is smaller than the capacitance Ccon of the output end capacitor 20. For example, the capacitance Cin is about several μF, and the capacitance Ccon is about several mF.

  Next, the rectifier module 15X will be described with reference to FIG. Since the rectifier modules 15X, 15Y, 15Z, 16U, 16V, and 16W have the same configuration, the rectifier module 15X will be described as a representative here.

  The rectifier module 15 </ b> X includes an upper switch 50, a lower switch 51, and a control circuit 54. The rectifier module 15X includes a B terminal (output terminal), a P terminal (phase voltage detection terminal), an E terminal (ground), and an RP terminal (signal output terminal).

  The upper switch 50 is a switching element on the upper arm (high side) of the rectifier circuit 15A, and the lower switch 51 is a switching element on the lower arm (low side) of the rectifier circuit 15A. In the present embodiment, the upper switch 50 and the lower switch 51 are N-channel MOSFETs. The upper switch 50 has a source terminal connected to the X-phase winding of the armature winding 11 via a P terminal, and a drain terminal connected to a B terminal which is an output terminal. The lower switch 51 has a drain terminal connected to the X-phase winding of the armature winding 11 via the P terminal, and a source terminal connected to the E terminal. That is, the source terminal of the upper switch 50 and the drain terminal of the lower switch 51 are connected.

  The gate terminal of the upper switch 50 is connected to the output terminal HG of the control circuit 54, and the gate terminal of the lower switch 51 is connected to the output terminal LG of the control circuit 54. The upper switch 50 and the lower switch 51 are turned on / off by a drive signal input from the control circuit 54 to the gate terminal. A body diode is connected in parallel between the source and drain of each of the upper switch 50 and the lower switch 51. The RP terminal is connected to the X-phase winding via the resistor 13.

  The control circuit 54 (switching control device) includes a power source 63 and a control unit 55. The power supply 63 supplies operating power to each element included in the control circuit 54 using the voltage at the B terminal.

  The control unit 55 performs synchronous rectification by transmitting a drive signal for turning on or off to the upper switch 50 and the lower switch 51 at normal times when no load dump occurs. Specifically, the upper switch 50 is turned on and the lower switch 51 is turned off over a period in which the phase voltage Vp input to the P terminal exceeds the output voltage Vb input to the B terminal. . Further, the upper switch 50 is turned off and the lower switch 51 is turned on over a period in which the phase voltage Vp is a negative voltage.

  In addition, when the load dump occurs, the control unit 55 keeps one of the upper switch 50 and the lower switch 51 in the off state until the energy accumulated in the armature winding 11 disappears, and turns on and off the other switch. Perform repeated load dump protection. In the present embodiment, a load dump protection operation is performed in which the lower switch 51 is repeatedly turned on and off while the upper switch 50 is in the off state. Specifically, the lower switch 51 is turned off, current is supplied from the armature winding 11 to the ground, and the lower switch 51 is turned on before the output voltage Vb becomes equal to or lower than the adjustment voltage Vref. Repeat recovery.

  Specifically, the control unit 55 includes functions of a voltage detection unit 56, a load dump detection unit 57, a protection unit 58, and a signal output unit 60. The voltage detector 56 detects the output voltage Vb, which is the voltage at the B terminal. The load dump detection unit 57 (detection unit) detects the occurrence of load dump when the output voltage Vb exceeds the threshold value Vth1 (first threshold value).

  FIGS. 5A and 6A are time charts of the output voltage Vb, the voltage Vcon between the terminals of the output-end capacitor 20, and the X-phase phase voltage Vp. FIG. 5B and FIG. 6B show time charts of drive signals for the lower switch 51. FIGS. 5C and 6D are time charts of the voltage VF at the F terminal, which is a regulator voltage. FIG. 6C shows a time chart of a pseudo signal Sp described later. Note that the inter-terminal voltage Vcon cannot be directly detected, and is an estimated value estimated from the output voltage Vb.

  When the output voltage Vb exceeds the threshold value Vth1 (first threshold value), the protection unit 58 turns on the lower switch 51 while keeping the upper switch 50 in the off state. At this time, the phase voltage Vp becomes 0V. 5 and 6, the delay time T1 is a delay time from the time point t10 and t20 when the output voltage Vb actually exceeds the threshold value Vth1 to the time point t11 and t21 when the lower switch 51 is turned on.

  The protection unit 58 turns the lower switch 51 off when the output voltage Vb drops to the threshold value Vth2 (second threshold value) as the lower switch 51 is turned on. The threshold value Vth2 is lower than the threshold value Vth1 and higher than the adjustment voltage Vref. At this time, the phase voltage Vp becomes the forward voltage of the body diode. 5 and 6, the delay time T2 is a delay time from time t12, t22 when the output voltage Vb actually decreases to the threshold value Vth2 to time t13, t23 when the lower switch 51 is turned off.

  The protection unit 58 repeats on / off of the lower switch 51 until the energy accumulated in the armature winding 11 disappears, and performs the load dump protection operation. The protection unit 58 accumulates in the armature winding 11 when the output voltage Vb continues to be lower than the threshold value Vth1 for a certain period of time or when the output voltage Vb continues to be lower than the threshold value Vth2 for a certain period of time. It is determined that the generated energy has been lost, and the load dump protection operation is terminated. In the present embodiment, the protection unit 58 protects the load dump when the output voltage Vb is continuously lower than the threshold value Vth1 for one cycle or more of the vehicle generator 10 after the lower switch 51 is turned off. End the operation. When the output voltage Vb falls below the adjustment voltage Vref after the load dump protection operation is completed, the supply of excitation current is resumed and power generation is resumed.

  When the load interruption occurs and the output voltage Vb exceeds the threshold value Vth1, the upper switch 50 is turned off and the lower switch 51 is turned on. At that time, if the lower switch 51 is turned on while the upper switch 50 is in the off state and the upper switch is energized, the current flows more easily in the lower switch 51 than in the diode connected in parallel to the upper switch 50. The output current Ib stops flowing, and the current flows through the lower switch 51. Along with this, a negative surge is generated at the B terminal due to the inductance L of the wiring 25 connected to the B terminal. As a result, as shown in FIG. 5A and FIG. 6A, the output voltage Vb drops rapidly to 0V. This negative surge is temporary due to the inductance L of the wiring 25 and disappears when the energy stored in the wiring 25 is exhausted.

  The power generation control device 17 is reset at time t11 and time t21 when the output voltage Vb suddenly drops to 0V. Accordingly, the gradual excitation unit 76a sets the initial value of the gradual excitation Duty and increases the Duty over a predetermined gradual excitation time. Thereafter, when the output voltage Vb recovers and the output voltage Vb drops to 0 V again at time points t14 and t24, the power generation control device 17 is reset again. Accordingly, the gradual excitation unit 76a sets the initial value of the gradual excitation duty counter again and increases the gradual excitation duty.

  Then, when the load dump protection operation by the protection unit 58 is completed, the power generation is resumed when the output voltage Vb is lower than the adjustment voltage Vref. Conventionally, when the rotational speed of the rotor is lower than the slow excitation cancellation rotational speed when power generation is resumed, the slow excitation section 76a, as shown in FIG. 5C, counts the slow excitation duty (from time t14 to time t15). The switching element 71 was controlled with the gradual excitation duty according to the time) and the gradual excitation was started.

  When the load dump is caused by the interruption of the load, a remaining load such as the load 31 may be connected to the wiring 25. When gradual excitation is performed to gradually increase the power generation amount with the remaining load connected to the wiring 25, the power generation amount becomes insufficient with respect to the power consumption amount of the load 31 before the power generation amount sufficiently increases, and the output The voltage Vb may be excessively reduced. If the output voltage Vb is excessively reduced, the power supply voltage is not supplied to the various ICs and ECUs such as the power generation control device 17 and the rectifier modules 15 and 16, and the various ICs and ECUs may stop and power generation may stop. is there. Therefore, when restarting power generation after the end of the load dump protection operation, it is desirable to perform normal power generation control without performing slow excitation.

  Therefore, the signal output unit 60 (pseudo signal unit), as shown in FIG. 6C, generates a pseudo signal Sp having a rotational speed higher than the slow excitation canceling rotational speed when the occurrence of load dump is detected. It transmits from the RP terminal to the RP terminal of the power generation control device 17. Thereby, the rotation detection circuit 77 of the power generation control device 17 recognizes the rotation speed of the rotor as the rotation speed of the pseudo signal Sp. Therefore, the gradual excitation unit 76a does not perform gradual excitation when restarting power generation after the end of the load dump protection operation. As shown in FIG. 6D, the excitation current control circuit 76 performs normal power generation control when the output voltage Vb becomes equal to or lower than the adjustment voltage Vref after the end of the load dump protection operation.

  Hereinafter, a specific configuration of the signal output unit 60 will be described with reference to FIG. The signal output unit 60 includes a series body of a resistor R1A and a switch SWA and a drive unit that drives the switch SWA. A series body of the resistor R1A and the switch SWA is connected between the B terminal and the RP terminal of the rectifier module 15X. The P terminal of the power generation control device 17 is connected to one end of the X-phase winding via the resistor 13 and the P terminal of the rectifier module 15X, and is connected to the RP terminal of the rectifier module 15X. When the switch SWA is turned on / off at a cycle according to a desired rotation speed, the pseudo signal Sp shown in FIG. 8B is input from the RP terminal of the rectifier module 15X to the P terminal of the power generation control device 17. The phase voltage Vp shown in FIG. 8A is also input to the P terminal of the power generation control device 17 via the P terminal of the rectifier module 15X and the resistor 13. Therefore, a signal obtained by superimposing the pseudo signal Sp on the phase voltage Vp shown in FIG. 9 is input to the P terminal of the power generation control device 17. By superimposing the pseudo signal Sp on the phase voltage Vp, the phase voltage Vp is raised according to the current flowing from the switch SWA (for example, 5 V).

  As shown in FIG. 6C, the signal output unit 60 starts driving the switch SWA and starts outputting the pseudo signal Sp at the time t25 when the end of the load dump protection operation is determined by the protection unit 58. To do. The power generation is resumed after the end of the load dump protection operation, but the signal output unit 60 may output the pseudo signal Sp before the end of the load dump protection operation. For example, the signal output unit 60 may start outputting the pseudo signal Sp from the time t20 when the output voltage Vb first exceeds the threshold value Vth1 or the time t21 when the load dump protection operation is started.

  Further, the signal output unit 60 continues to output the pseudo signal Sp until the gradual excitation canceling function by the canceling unit 76b becomes effective. As described above, the invalidation unit 76c invalidates the cancellation of gradual excitation by the cancellation unit 76b for a predetermined period after the reset of the power generation control device 17 or the start of the engine 200 is detected. The signal output unit 60 continues to output the pseudo signal Sp until the predetermined period ends. For example, when the invalidation unit 76c invalidates the cancellation of the gradual excitation with a predetermined period from the time point t24 to the time point t27, the signal output unit 60 can output the pseudo signal Sp from any time point. The pseudo signal Sp is continuously output until t27. After the gradual excitation canceling function by the cancel unit 76b is enabled, the gradual excitation is canceled and the power generation amount increases when the output voltage Vb decreases. Therefore, after the gradual excitation canceling function is enabled, an excessive decrease in the output voltage Vb is suppressed without transmitting the pseudo signal Sp.

  The rotation detection circuit 77 of the power generation control device 17 reads the period of the pseudo signal Sp and detects the rotation speed. Therefore, even when the actual rotational speed of the rotor is lower than the slow excitation cancellation rotational speed, it is recognized as a rotational speed higher than the slow excitation rotational speed. As a result, as shown in FIG. 6D, after the load dump protection operation is completed, the slow excitation is not performed and normal power generation control is performed.

  Even when some elements of the control circuit 54 fail and the upper switch 50 and the lower switch 51 are not turned on, the phase voltage Vp is input to the P terminal of the power generation control device 17 via the resistor 13. Is done. Therefore, even if some elements of the control circuit 54 fail, the power generation control device 17 can continue the power generation control by detecting the phase voltage Vp. When the upper switch 50 or the lower switch 51 is not turned on, rectification by the body diode is performed.

  Next, the processing procedure of the load dump protection operation will be described with reference to the flowchart of FIG. This processing procedure is repeatedly executed by the control unit 55 at predetermined intervals.

  First, it is determined whether or not power generation is in progress (S10). When the power generation is not in progress (S10: NO), the process of S10 is repeated. If power is being generated (S10: YES), it is next determined whether or not the output voltage Vb is larger than the threshold value Vth1 (S11). That is, it is determined whether a load dump has occurred and an overvoltage has occurred. When the output voltage Vb is less than or equal to the threshold value Vth1 (S11: NO), it is determined that no load dump has occurred, and the process returns to S10.

  On the other hand, when the output voltage Vb is larger than the threshold value Vth1 (S11: YES), it is determined that a load dump has occurred, and the load dump protection operation is started. First, the upper switch 50 is turned off and the lower switch 51 is turned on (S12).

  Subsequently, it is determined whether or not the output voltage Vb is lower than the threshold value Vth2 (S13). When the output voltage Vb is equal to or higher than the threshold value Vth2 (S13: NO), the process of S13 is repeatedly executed. On the other hand, when the output voltage Vb is lower than the threshold value Vth2 (S13: YES), the lower switch 51 is turned off while the upper switch 50 is turned off (S14).

  Subsequently, it is determined whether or not the state in which the output voltage Vb is lower than the threshold value Vth1 continues for one or more cycles of the vehicular generator 10 after the lower switch 51 is switched off (S15). That is, it is determined whether the energy accumulated in the armature winding 11 has disappeared.

  If the output voltage Vb exceeds the threshold value Vth1 before one cycle of the vehicle generator 10 elapses after the lower switch 51 is switched to the on state (S15: NO), the process returns to S12 to load Repeat the dump protection operation. On the other hand, when the output voltage Vb continues to be lower than the threshold value Vth1 from when the lower switch 51 is switched to the OFF state until one cycle of the vehicle generator 10 elapses (S15: YES), the load The dump protection operation is finished and the output of the pseudo signal Sp is started (S16). This process is complete | finished above.

  According to 1st Embodiment described above, there exist the following effects.

  (1) When the occurrence of a load dump is detected, a pseudo signal Sp having a rotational speed higher than the gradual excitation canceling rotational speed is output from the signal output unit 60 of the rectifier module 15X to the power generation control device 17. Thereby, even if the actual rotational speed is lower than the slow excitation canceling rotational speed after the end of the load dump protection operation, it is recognized as a rotational speed higher than the slow excitation canceling rotational speed. Therefore, when the load dump protection operation is finished and the power generation is restarted, it is possible to suppress the gradual excitation.

  (2) Since the gradual excitation is not stopped even if the output voltage Vb becomes lower than the predetermined voltage from when the reset of the power generation control device 17 or the start of the engine 200 is detected until the predetermined period elapses, the low load In this state, the engine 200 can be reliably started.

  (3) When the occurrence of a load dump is detected, the pseudo signal Sp is output until the slow excitation cancel function is enabled. Therefore, when the power generation control device 17 is reset due to the occurrence of the load dump and the start of the engine 200 is erroneously detected, it is possible to suppress the gradual excitation after the end of the load dump protection operation. In addition, after the gradual excitation cancel function is enabled, the gradual excitation is stopped if the output voltage Vb falls below a predetermined voltage, so that the output voltage Vb does not fall below the predetermined voltage. Therefore, an excessive decrease in the output voltage Vb can be suppressed and power generation stoppage can be suppressed.

  (4) Since the signal obtained by superimposing the pseudo signal Sp on the phase voltage Vp is input to the P terminal of the power generation control device 17, the power generation control device 17 reads the pseudo signal Sp and determines the rotational speed from the gradual excitation cancel rotation speed. A high rotational speed can be detected.

  (5) Since the phase voltage Vp is input to the P terminal of the power generation control device 17 via the resistor 13 even if the upper switch 50 and the lower switch 51 remain in the OFF state, the power generation control device 17 generates power. Control can be continued.

(Second Embodiment)
The rectifier modules 15 and 16 according to the second embodiment are different from the rectifier modules 15 and 16 according to the first embodiment in the configuration of the signal output unit 60. Moreover, in 2nd Embodiment, the resistance 13 shown with a broken line in FIG.2 and FIG.3 is not connected. That is, in the second embodiment, the RP terminal of the rectifier module 15 </ b> X and the P terminal of the power generation control device 17 are not connected to the armature windings 11 and 12 via the resistor 13.

  Hereinafter, the configuration of the signal output unit 60 according to the second embodiment will be described with reference to FIG. The signal output unit 60 according to the second embodiment includes a series body of a resistor R1B and a switch SWB, a switch SWC, and a drive unit that drives the switch SWB and the switch SWC. A series body of the resistor R1B and the switch SWB is connected between the B terminal and the RP terminal of the rectifier module 15X. The switch SWC is connected between the P terminal and the RP terminal of the rectifier module X.

  When the switch SWC is turned on, the phase voltage Vp is input from the RP terminal of the rectifier module 15X to the P terminal of the power generation control device 17 via the switch SWC. When the switch SWB is turned on / off at a cycle according to a desired rotation speed, the pseudo signal Sp shown in FIG. 12 is input from the RP terminal of the rectifier module 15X to the P terminal of the power generation control device 17. By making the resistance value of the resistor R2B sufficiently larger than the resistance value of the resistor R1B, the amplitude of the pseudo signal Sp is made substantially equal to the phase voltage Vp. In the present embodiment, the switch SWC corresponds to the first path that outputs the phase voltage Vp, and the series body of the resistor R1B and the switch SWB corresponds to the second path that outputs the pseudo signal Sp. Note that a voltage follower may be connected to the first path in series with the switch SWC.

  In the present embodiment, normally, the switch SWB is turned off and the switch SWC is turned on so that the phase voltage Vp is input to the P terminal of the power generation control device 17. On the other hand, when the occurrence of the load dump is detected, the switch SWC is turned on and off while the switch SWC is in the off state so that the pseudo signal Sp is input to the P terminal of the power generation control device 17. That is, in this embodiment, the pseudo signal Sp is not superimposed on the phase voltage Vp. In the present embodiment, the path in the signal output unit 60 is switched between a normal time and a load dump occurrence, and either the phase voltage Vp or the pseudo signal Sp is output to the P terminal of the power generation control device 17. Yes. In the present embodiment, when the switch SWC fails and is not turned on at normal times, the phase voltage Vp is not input to the P terminal of the power generation control device 17, so that the power generation control device 17 can continue the power generation control. Disappear.

  In this embodiment, since the pseudo signal Sp is not superimposed on the phase voltage Vp, the pseudo signal Sp having an ideal waveform is input to the P terminal of the power generation control device 17. Therefore, the possibility that the rotation detection circuit 77 of the power generation control device 17 erroneously detects the rotation speed of the pseudo signal Sp is suppressed.

  In the present embodiment, it is not necessary to connect the resistor 13 between one end of the armature winding 11 and the P terminal of the power generation control device 17. Generally, when an element is connected in a module such as the rectifier module 15X or the power generation control device 17, it can be connected relatively easily. On the other hand, when connecting an element outside the module, such as between one end of the armature winding 11 and the P terminal of the power generation control device 17, it is necessary to perform welding processing, waterproof processing, etc. It takes time and effort. As a result, the manufacturing cost increases. In this embodiment, since the resistor 13 is not connected, the labor and manufacturing cost during manufacturing are reduced.

  According to 2nd Embodiment demonstrated above, while there exists an effect similar to (1)-(3) of 1st Embodiment, there exist the following effects.

  (6) By not superimposing the pseudo signal Sp on the phase voltage Vp, the pseudo signal Sp having an ideal waveform is input to the P terminal of the power generation control device 17. Therefore, erroneous detection of the rotational speed of the pseudo signal Sp can be suppressed as compared with the case where the pseudo signal Sp is superimposed on the phase voltage Vp.

  (7) Since the pseudo signal Sp is not superimposed on the phase voltage Vp, the resistor 13 is not connected between one end of the armature winding 11 and the P terminal of the power generation control device 17. Therefore, it is possible to reduce the labor of processing at the time of manufacturing, and consequently to reduce the manufacturing cost.

(Other embodiments)
A single rectifier module may be provided with switching elements for two or more phases and control on / off of switching elements for two or more phases. Further, a common control circuit may be provided for all the switching elements, and the on / off of all the switching elements may be controlled by one control circuit.

  The upper switch 50 and the lower switch 51 are not limited to MOSFETs but may be semiconductor switches such as IGBTs or bipolar transistors.

  Only one of the upper arm and the lower arm of the rectifier module groups 15 and 16 may be configured with a switching element, and the other may be configured with a diode. In this case, the load dump protection operation is performed by turning on and off the arm of the switching element.

  -The generator 10 for vehicles may be 3 phases other than 6 phases, for example, provided with only the armature winding 11. The armature windings 11 and 12 are not limited to three phases, and may be two phases or four or more phases.

  DESCRIPTION OF SYMBOLS 10 ... Generator for vehicles, 11, 12 ... Armature winding, 14 ... Field winding, 15A ... Rectification circuit, 17 ... Power generation control apparatus, 54 ... Control circuit, 140 ... Rotary shaft, 200 ... Engine.

Claims (4)

A rotating electrical machine (10) for a vehicle in which a rotating shaft (140) is connected to a rotating shaft of an internal combustion engine (200),
A field winding (14) for magnetizing the rotor field poles;
A plurality of armature windings (11, 12) for generating an alternating voltage by a rotating magnetic field generated by the field pole;
A rectifier circuit (15A) having an upper arm and a lower arm, wherein at least one of the upper arm and the lower arm is constituted by a switching element, and rectifies and outputs an induced voltage of the armature winding )When,
A power generation control device (17) for adjusting the excitation current supplied to the field winding to control the output voltage of the rectifier circuit;
A switching control device (54) for controlling on / off of the switching element,
The power generation control device
When the reset of the power generation control device or the start of the internal combustion engine is detected and the rotational speed of the rotor is lower than a predetermined rotational speed, the gradual excitation is performed to gradually increase the power generation amount for a predetermined gradual excitation period. It has a gradual excitation part,
The switching control device includes:
A detection unit for detecting the occurrence of a load dump when the output voltage exceeds a first threshold;
When the output voltage exceeds the first threshold, the switching element of one of the upper arm and the lower arm is turned on, and the output voltage is reduced to a second threshold lower than the first threshold. A protective unit that turns off the one switching element,
And a pseudo signal unit that outputs a pseudo signal having a rotational speed higher than the predetermined rotational speed to the power generation control device when occurrence of the load dump is detected by the detection unit. Rotating electric machine. The power generation control device
When the output voltage becomes lower than a predetermined voltage, a cancellation unit that cancels the gradual excitation,
A disabling unit that disables the cancellation of the slow excitation by the canceling unit for a predetermined period after the reset of the power generation control device or the start of the internal combustion engine is detected,
The rotating electrical machine for a vehicle according to claim 1, wherein the pseudo signal unit transmits the pseudo signal to the power generation control device until a cancel function by the cancel unit becomes effective. The power generation control device includes a speed detection terminal (P) for detecting the rotational speed of the rotor,
The switching control device includes a signal output terminal (RP) that outputs the pseudo signal,
The speed detection terminal is connected to one end of the armature winding via a resistor (13) and to the signal output terminal. Rotating electric machine for vehicles. The switching control device includes a first path (SWC) that outputs a phase voltage of the armature winding, and a second path (R1B, SWB) that outputs the pseudo signal,
The pseudo signal unit disconnects the connection between the first path and the power generation control device when the generation of the load dump is detected by the detection unit, and connects the second path and the power generation control device. The rotating electrical machine for a vehicle according to claim 1, wherein the rotating electrical machine is connected.

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