JP2004122925A - Hybrid motorcycle and its power transmission device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power transmission device for a hybrid motorcycle capable of performing an engine start, an assist and a battery charging using a small-type rotating electric machine. <P>SOLUTION: The power transmission device consists of a first power transmission part 10A which transmits the rotation of a rotating shaft 2a of the rotating electric machine 2 to a crank shaft 1a of an engine 1 through a reducer 11 and a one-way clutch 12, and a second power transmission part 10B which transmits the rotation of the rotating electric machine 2 to the crank shaft 1a through an electromagnetic clutch 14 and a power transmission mechanism 13 having a smaller reduction ratio than the reducer 11 which are provided between the rotating shaft of the rotating electric machine and the crank shaft of the engine. The electromagnetic clutch 14 is set to be in an OFF state at the time of engine start, and the electromagnetic clutch 14 is set to be in an ON state after the engine start. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention includes an engine that drives driving wheels of a motorcycle, and a rotating electric machine in which a rotating shaft is connected to a crankshaft of the engine via a power transmission device. When the engine is started, the rotating electric machine is used as an engine starting motor. A hybrid in which the rotating electric machine is operated as an electric motor to assist the engine with the rotating electric machine after the engine is started or the rotating electric machine is driven by the engine to operate the rotating electric machine as a generator for charging a battery. The present invention relates to a motorcycle and a power transmission device used for the hybrid motorcycle.
[0002]
[Prior art]
The required operating characteristics are different between the starting motor used to start the engine and the motor for assisting the engine. When starting the engine with the starting motor, it is necessary to generate a large torque in order to crank the engine.However, since it is only necessary to be able to start the engine, it is not necessary that the rotation speed of the motor be so high. Instead, its no-load rotational speed may be lower than the idling speed of the engine.
[0003]
On the other hand, after the engine is started, when assisting the engine with the electric motor (to help drive the load by the engine), the no-load rotation speed of the electric motor is set sufficiently higher than the idling speed of the engine, and the idling speed of the electric motor is increased. It must be possible to drive at higher speeds. Generally, the no-load rotation speed of the electric motor during engine assist is often set to a speed near the rotation speed at which the output of the engine reaches a peak.
[0004]
FIG. 8 shows the rotational speed versus output torque characteristics required of the electric motor when starting the engine and assisting the engine. Curve a in FIG. 8 is required when starting the engine. The curve b shows the characteristics required when assisting the engine.
[0005]
If the crankshaft of the engine and the rotating shaft of one electric motor are connected at a reduction ratio of 1: 1 and the motor is used to start the engine and assist, the electric motor starts the engine. It is necessary to have a characteristic such as a curve c in FIG. 8 that satisfies both the characteristic required at times and the characteristic required at the time of assisting.
[0006]
When operating as a motor, a rotating electric machine having a characteristic as shown by a curve c in FIG. 8 is operated as a generator to charge a battery with the output of the rotating electric machine. There is a possibility that the charging current flowing to the battery becomes excessive, and it is not easy to adjust the output voltage to prevent the battery from being overcharged. If the rotating electric machine is of a magnet field rotating type having a magnet rotor, the voltage can be adjusted by short-circuiting the output of the rotating electric machine when the power generation output becomes excessive. In this case, since a large short-circuit current flows through the armature winding of the rotating electric machine, heat generation from the winding increases, which is not preferable. In addition, the rotating electric machine having the characteristics such as the curve c in FIG. 8 is inevitably large in size and heavy in weight and high in cost.
[0007]
Therefore, as shown in FIG. 9, between the crankshaft of the engine (E / G) 1 and the rotating shaft of the rotary electric machine 2, for example, a CVT (belt type unauthorized) in which the reduction ratio decreases as the rotation speed increases. When the engine is started with the transmission 3 interposed therebetween, the rotation of the rotating electric machine is reduced at a large reduction ratio and transmitted to the crankshaft of the engine, and when assisting the engine, the rotation of the rotating electric machine is reduced. It is conceivable that the speed is reduced at a small reduction ratio and transmitted to the crankshaft of the engine.
[0008]
The rotating electric machine shown in FIG. 9 is a rotating type of a magnet field including a rotor having a magnet field, and a stator having a three-phase armature coil wound around an armature core. When operating as a starting motor and when operating as an engine assist motor, the motor is driven in the same manner as a brushless DC motor. Therefore, the output of the battery 4 is applied to the armature coil of the rotating electric machine 2 via the inverter 5, and a position detection signal obtained from a position sensor for detecting the rotation angle position of the rotor of the rotating electric machine 2, and the position of the accelerator grip Is provided with a controller 7 for controlling the inverter 5 in accordance with the output of the accelerator position sensor 6 for detecting the acceleration.
[0009]
In the example shown in FIG. 9, when starting the engine, a driving current commutated according to the rotation angle position of the rotor of the rotating electric machine 2 is supplied from the battery to the three-phase armature coil of the rotating electric machine through the inverter 5. Then, the controller 5 controls the inverter 5 to operate the rotating electric machine 2 as a brushless DC motor. Thus, the output torque of the rotating electrical machine is multiplied by the reduction ratio of the CVT and transmitted to the crankshaft of the engine, and the engine is cranked and started.
[0010]
The controller 7 also controls the inverter so that the rotating electric machine operates as a brushless DC motor when assisting the engine by operating the rotating electric machine as a motor when the motorcycle is running, and at the same time, averages the driving current of the rotating electric machine. In accordance with the accelerator position, the drive current supplied to the rotating electric machine through the inverter 5 is PWM-controlled so that is a value suitable for the accelerator position detected by the accelerator position sensor 6.
[0011]
When the rotation speed of the engine exceeds the no-load rotation speed of the rotating electric machine while the motorcycle is running, the rotating electric machine is driven by the engine to operate the rotating electric machine as a generator. The output alternating current is supplied to the battery 4 through a rectifier circuit provided in the inverter 5.
[0012]
As described above, when the voltage across the battery 4 exceeds the target value while the rotating electric machine is operating as a generator, the controller 7 turns on a predetermined switching element included in the inverter 5 by turning on the switching element. A short circuit for shorting the output of the rotating electric machine is formed in the inverter. Thus, the output of the rotating electric machine is suppressed, and overcharging of the battery 4 is prevented.
[0013]
When the rotating shaft of the rotating electric machine is coupled to the crankshaft of the engine via the CVT as described above, a large torque determined by the product of the output torque of the rotating electric machine and a large reduction ratio of the CVT at the time of starting the engine is generated by the crankshaft. Since the electric power can be transmitted to the shaft, the engine can be started even if a small rotating electric machine 2 having a small output torque is used. Since a small-sized rotating electric machine 2 can be used, it is possible to prevent the output of the generator from becoming excessive when the rotating electric machine is operated as a generator.
[0014]
However, the CVT in which the reduction ratio changes in accordance with the rotation speed of the engine has a complicated structure and is expensive. Therefore, when the above-described configuration is adopted, the ratio of the power transmission device to the cost of the hybrid motorcycle is low. It is too large, which is not preferable.
[0015]
It is preferable that the power transmission device used for the hybrid motorcycle be as simple as possible in structure, inexpensive, and small in size.
[0016]
2. Description of the Related Art As a prior art relating to a rotating electric machine for a vehicle, for example, as shown in Patent Document 1, a starting electric motor is provided by interposing a planetary gear mechanism between a rotating shaft of the rotating electric machine and a crankshaft of an engine. However, the planetary gear mechanism is complex and expensive, so it is not suitable as a transmission for motorcycles that emphasizes simple and inexpensive. is there.
[0017]
Further, the rotating electric machine disclosed in Patent Document 1 can operate as a starting motor and a generator for charging a battery, but cannot operate as an assist motor for assisting an engine.
[0018]
[Patent Document 1]
JP 2001-298900 A
[0019]
[Problems to be solved by the invention]
The conventional power transmission device disclosed in Patent Literature 1 is not suitable as a power transmission device used for a motorcycle because its structure is complicated and expensive.
[0020]
Further, in the conventional power transmission device, after the engine is started, the rotating electric machine is operated solely as a generator, so that there is a problem that the rotating electric machine becomes a load on the engine even when it is not necessary to charge the battery. Was.
[0021]
An object of the present invention is to use a small rotating electric machine and a power transmission device having a simple structure to convert the rotating electric machine into three parts: an electric motor for starting the engine, an electric motor for assisting the engine, and a generator for charging the battery. An object of the present invention is to provide a hybrid motorcycle that can be driven in a form.
[0022]
Another object of the present invention is to transmit the rotation of a rotating electric machine to a crankshaft of the engine with a large reduction ratio at the time of starting the engine, thereby enabling the engine to be started with a small rotating electric machine. By connecting the rotating electric machine and the crankshaft of the engine with a smaller reduction ratio than at the start, it is possible to operate the rotating electric machine as an electric motor for engine assist or as a generator for battery charging To provide a power transmission device for a hybrid motorcycle.
[0023]
[Means for Solving the Problems]
The present invention includes an engine that drives driving wheels of a motorcycle, a rotating electric machine that also serves as a generator and an electric motor, and a power transmission device provided between a crankshaft of the engine and a rotating shaft of the rotating electric machine. The rotating electric machine is operated as a starter motor that drives the crankshaft of the engine when the engine is started, is operated as an assist motor that assists the engine as needed when the motorcycle is operating, and a battery mounted on the motorcycle is used. The present invention relates to a hybrid motorcycle which is operated as a generator for charging a battery by using an engine as a driving source when charging.
[0024]
In the present invention, the power transmission device includes a first power transmission unit and a second power transmission unit. The first power transmission unit includes a speed reducer that reduces the rotation of the rotating shaft of the rotating electric machine, and a one-way clutch that only transmits power from the rotating electric machine to the crankshaft side of the engine. The rotation of the shaft is transmitted to the crankshaft of the engine through the reduction gear and the one-way clutch. The second power transmission unit includes a power transmission mechanism and an electromagnetic clutch, and transmits power between the rotating shaft of the rotating electric machine and the crankshaft of the engine through the power transmission mechanism and the electromagnetic clutch. Be composed.
[0025]
The reduction ratio of the speed reducer of the first power transmission unit is such that when the rotating electric machine is operated as an engine starting motor, torque required for performing cranking is transmitted from the rotating electric machine to the crankshaft of the engine. (For example, 4: 1).
[0026]
The power transmission mechanism of the second power transmission unit is configured such that the reduction ratio viewed from the rotating electric machine side is smaller than the reduction ratio of the speed reducer of the first power transmission unit.
[0027]
The “reduction ratio” is a ratio N1: N2 between the rotation speed N1 of the rotation shaft of the power transmission mechanism on the rotating electric machine side and the rotation speed N2 of the rotation shaft of the power transmission mechanism on the engine side.
[0028]
That is, the power transmission mechanism of the second power transmission unit reduces the rotation of the rotary electric machine at a reduction ratio smaller than the reduction ratio of the speed reducer of the first power transmission unit when assisting the engine with the rotary electric machine, Alternatively, it is configured to increase the speed or to transmit to the crankshaft without reducing or increasing the speed (at a reduction ratio of 1: 1).
[0029]
In the present invention, there is further provided a controller for controlling the electromagnetic clutch so that the electromagnetic clutch is turned off when the engine is started, and the electromagnetic clutch is turned on when necessary after the engine is started.
[0030]
With this configuration, the engine can be started using a small rotating electric machine by setting the reduction ratio of the first power transmission unit to a sufficiently large value. After the engine is started, the electromagnetic clutch is turned on, and the rotation of the rotating electric machine is transmitted to the engine through the second power transmission unit having a reduction ratio smaller than the reduction ratio of the speed reducer of the first power transmission unit. Therefore, the engine can be assisted by operating the rotating electric machine as a motor, or the rotating electric machine can be operated as a generator to charge a battery with the output of the rotating electric machine.
[0031]
As described above, according to the present invention, the rotating electric machine can be configured to be small, so that when the rotating electric machine is operated as a generator, the power generation output does not become excessive. Therefore, when voltage is adjusted by short-circuiting the output of the rotating electric machine, a large short-circuit current can be prevented from flowing, and a rise in the temperature of the armature coil during voltage adjustment can be suppressed.
[0032]
In a preferred aspect of the present invention, when the rotating electric machine is operated as an electric motor to assist the engine after the engine is started, and when the rotating electric machine is operated as a generator and the battery is charged by the output of the generator. The electromagnetic clutch is turned on, and even when the engine is running, there is no need to assist the engine with the rotating electric machine, and when there is no need to charge the battery with the rotating electric machine, the electromagnetic clutch is turned off so that the electromagnetic clutch is turned off. A controller is configured to control.
[0033]
In this way, if the rotating electrical machine is disconnected from the engine by turning off the electromagnetic clutch when the charging of the battery is completed, it is not necessary to adjust the power generation output of the rotating electrical machine. The temperature can be prevented from rising. When the controller is configured as described above, the electromagnetic clutch is turned off to disconnect the rotating electric machine from the engine when the battery is in a fully charged state and it is not necessary to operate the rotating electric machine as an electric motor to assist the engine. Therefore, fuel efficiency of the engine can be saved. When the rotating speed of the engine exceeds the no-load rotating speed of the rotating electric machine when the battery is fully charged, the load on the engine can be reduced by turning off the electromagnetic clutch and disconnecting the rotating electric machine from the engine. Therefore, the acceleration performance of the engine can be improved.
[0034]
The present invention also operates as an engine that drives the drive wheels of a motorcycle, and as a starter motor that drives the crankshaft of the engine when the engine is started, and operates as an assist motor that assists the engine as needed during the operation of the motorcycle. When charging the battery mounted on the motorcycle, the rotating shaft of the engine and the rotating shaft of the rotating electric machine of the engine of the hybrid motorcycle having a rotating electric machine driven by the engine as a driving source and a generator for charging the battery. It is applied to a power transmission device provided between them.
[0035]
The power transmission device according to the present invention includes a speed reducer that reduces the rotation of the rotating shaft of the rotating electric machine, and a one-way clutch that only transmits power from the rotating electric machine to the crankshaft side of the engine. A first power transmission unit configured to transmit rotation of the rotating shaft to a crankshaft of the engine through a speed reducer and a one-way clutch; a rotating shaft of a rotating electric machine and a crankshaft of the engine through a power transmitting mechanism and an electromagnetic clutch; And a second power transmission unit configured to transmit power between the power transmission unit and the power transmission unit. In the power transmission mechanism of the second power transmission unit, the reduction ratio as viewed from the rotating electric machine side is smaller than the reduction ratio of the speed reducer of the first power transmission unit (when the reduction ratio is 1: 1 and when the speed increase Is included.)
[0036]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 schematically shows a configuration of a first embodiment of the present invention. In FIG. 1, reference numeral 1 denotes an engine, and 2 denotes a rotating electric machine.
[0037]
The rotating electric machine 2 winds three-phase armature coils Lu, Lv, and Lw (see FIG. 2) around an armature core having a magnet rotor having a magnet field and a magnetic pole portion facing the magnetic pole of the rotor. And a stator in which the three-phase armature coils are star-connected.
The rotating electric machine 2 may be an outer rotor type or an inner rotor type.
[0038]
Reference numeral 4 denotes a battery. The output of the battery 4 is supplied to the rotating electric machine 2 through an inverter 5. The inverter 5 includes, for example, as shown in FIG. 2, a bridge circuit of switch elements configured by connecting three switch elements Qu, Qv, Qw, Qx, Qy, and Qz that can be turned on and off in a three-phase bridge. A known bridge-type inverter including feedback diodes Du, Dv, Dw, Dx, Dy, and Dz connected in anti-parallel to switch elements Qu, Qv, Qw, Qx, Qy, and Qz constituting the bridge circuit, respectively. A capacitor Ca is connected between the DC terminals 5a and 5b of the inverter 5. In the illustrated example, MOSFETs are used as the switching elements Qu, Qv, Qw, Qx, Qy and Qz constituting the inverter, and a parasitic diode formed between the drain and source of the FET constituting these switches is a feedback diode Du. , Dv, Dw, Dx, Dy and Dz.
[0039]
The switch element used for the inverter is not limited to the FET, but may be a bipolar transistor, an IGBT, or the like.
[0040]
The battery 4 is connected between the DC side terminals 5a and 5b of the inverter 5, and the three-phase AC terminals 5u, 5v and 5w of the inverter 5 are connected to the three-phase armature coils Lu, Lv and Lw of the rotary electric machine 2, respectively. The extracted three-phase terminals are connected.
[0041]
Reference numeral 7 denotes a controller including a microprocessor and a drive circuit of an inverter. Control terminals of the six switch elements Qu, Qv, Qw, Qx, Qy, and Qz of the inverter 5 from the drive circuit of the controller 7 (in the illustrated example, Drive signals (signals for turning on the switching elements) U, V, W, X, Y, and Z are supplied to the gates of the FETs.
[0042]
The controller 7 includes outputs Hu, Hv, and Hw of position sensors hu, hv, and hw for detecting the rotational angle position of the magnet field of the rotor of the rotary electric machine 2, and an accelerator position sensor 6 for detecting the position of the accelerator grip. Output and is input.
[0043]
The position sensors hu to hw for detecting the rotation angle position of the magnet field of the rotor of the rotating electric machine are usually formed of Hall ICs, and are provided for each of the three-phase armature coils of the rotating electric machine. The position sensors hu to hw detect the polarity of the magnetic pole of the rotor (not shown) at predetermined detection positions set for the three-phase armature coils Lu to Lw, respectively. It outputs rectangular wave position detection signals Hu, Hv and Hw indicating a high level or a low level accordingly.
[0044]
When operating the rotating electric machine as an electric motor, the controller 7 needs to excite the rotor of the rotating electric machine in a predetermined direction (a direction for starting the engine or a direction for assisting the engine) based on the position detection signal. A drive signal is supplied from the drive circuit to a predetermined switch element (switch element to be turned on) of the inverter 5 so as to determine a certain phase (excitation phase) and to apply a drive current to the armature coil of the determined excitation phase. .
[0045]
The accelerator position sensor 6 includes a potentiometer having an input shaft connected to an accelerator grip, and generates an electric signal proportional to the accelerator position. When operating the rotating electric machine as an electric motor, the controller 7 sets a switch element forming an upper side or a lower side of a bridge of the inverter 5 to a predetermined value so that an average value of the armature current of the electric motor is set to a value corresponding to an accelerator position. And a PWM control of a drive current supplied from the battery 4 to the rotary electric machine 2 through the inverter 5.
[0046]
As shown in FIG. 1, a power including a first power transmission unit 10 </ b> A and a second power transmission unit 10 </ b> B is provided between a crankshaft 1 a of the engine 1 and a rotation shaft 2 a of the rotary electric machine 2. A transmission device 10 is provided.
[0047]
The first power transmission unit 10A includes a speed reducer 11 that reduces the rotation of the rotating shaft of the rotary electric machine 2, and a one-way clutch 12 that only transmits power from the rotary electric machine 2 to the crankshaft of the engine 1. It is configured to transmit the rotation of the rotating shaft 2a of the rotating electric machine 2 to the crank 1a shaft of the engine 1 through the reduction gear 11 and the one-way clutch 12.
[0048]
The illustrated reduction gear 11 is connected to a reduction gear small spur gear 11 a mounted on a rotating shaft 2 a of the rotary electric machine 2 via a one-way clutch 12 and connected to a crankshaft 1 a of the engine 1 through a reduction gear engaged with the small spur gear 11 a. And a large spur gear 11b.
[0049]
The second power transmission unit 10 </ b> B includes a power transmission mechanism 13 and an electromagnetic clutch 14. The rotation shaft 2 a of the rotary electric machine 2 and the crankshaft 1 a of the engine 1 pass through the power transmission mechanism 13 and the electromagnetic clutch 14. It is configured to transmit power between the two.
[0050]
The illustrated power transmission mechanism 13 includes first and second spur gears 13a and 13b meshed with each other. The first spur gear 13a is connected to a rotating shaft 2a of the rotary electric machine 2 via an electromagnetic clutch 14. It is attached to the connected rotary shaft 15. The second spur gear 13 </ b> B is mounted on a rotating shaft 16 directly connected to the crankshaft 1 a of the engine 1.
[0051]
The power transmission mechanism 13 provided in the second power transmission unit 10B is configured such that the reduction ratio viewed from the rotating electric machine 2 side is smaller than the reduction ratio of the reduction gear 11 of the first power transmission unit 10A.
[0052]
In the illustrated example, the reduction ratio of the reduction gear 11 is set to 4: 1 and the reduction ratio of the power transmission mechanism 13 is set to 1: 1.
[0053]
The electromagnetic clutch 14 is off when the engine is stopped, and cuts off transmission of power between the rotating shaft 2 a of the rotary electric machine 2 and the power transmission mechanism 13.
[0054]
The controller 7 keeps the electromagnetic clutch 14 off when the engine 1 is started, in addition to the means for controlling the inverter 5 as described above when operating the rotating electric machine 2 as an electric motor, and after the engine 1 is started. An electromagnetic clutch control unit that controls the electromagnetic clutch 14 so that the electromagnetic clutch 14 is turned on when necessary is provided.
[0055]
FIG. 3 shows that the microprocessor of the controller 7 detects the switching of the rising or falling level of each of a series of outputs Hu, Hv and Hw sequentially output from the Hall ICs constituting the position sensors hu, hv and hw. FIG. 3 shows an example of an electromagnetic clutch control routine executed every time.
[0056]
In the case of the algorithm shown in FIG. 3, when the switching of the rising or falling level of the position detection signals Hu, Hv and Hw is detected, the step 1 of FIG. 3 is executed, and the previous level switching is detected. The time from when the switching of the current level is detected until this time is detected is read as the Hall IC switching time T (the time required for the rotating shaft of the rotating electric machine to rotate by 120 °). Next, in step 2, the rotation speed N of the rotary electric machine 2 is calculated from the time T, and in step 3, the rotation speed N is compared with a determination rotation speed Ni for determining that the start of the engine has been completed. As a result, when it is determined that Ni> N, the routine proceeds to step 4, where it is determined that the engine has not been started, and the electromagnetic clutch 14 is kept off to end this routine. When it is determined in step 3 that Ni ≦ N, the process proceeds to step 5 where it is determined that the start of the engine is completed, and the electromagnetic clutch 6 is turned on.
[0057]
The controller 7 also includes voltage adjusting means for controlling the inverter 5 so that the voltage across the battery mounted on the motorcycle is maintained at a target value. The voltage adjusting means detects the voltage of the battery, and performs chopper control or drive control to charge the battery when the detected voltage is lower than the target value and the rotation speed is equal to or lower than the no-load rotation speed. When the voltage is lower than the target value and the rotation speed is equal to or higher than the no-load rotation speed, the drive is controlled to charge the battery, or the battery is charged in the rectification mode (mode in which all the switch elements of the inverter are turned off). Charge the battery. When the detected voltage is higher than the target value and the rotational speed is equal to or lower than the no-load rotational speed, the voltage adjusting means turns off all the switching elements of the inverter, and the detected voltage is higher than the target value and When the speed exceeds the no-load rotation speed, drive control or short-circuit control is performed to control the voltage at both ends of the battery to a target value.
[0058]
In the drive control, the inverter is configured to apply an AC control voltage having a predetermined phase angle with respect to the induced voltage of the armature coil from the battery to the armature coil through the inverter in the rotating rotating electric machine of the magnet field rotation type. A drive period (a period in which the switch element is turned on) and a non-drive period (a period in which the switch element is turned off) are determined, and each switch element is turned on for a predetermined drive period. A switch control device for supplying a drive signal to each switch element for performing the operation is provided, so that an output (an output voltage or an output current of the rotating electric machine) vs. a rotational speed characteristic is set to an expected characteristic with respect to an induced voltage of the armature coil. This is control for changing the phase of the control voltage.
[0059]
In a rotating electric machine of a magnet field rotating type, a magnetic field acting on an armature coil can be controlled by changing a phase of an AC control voltage with respect to an induced voltage of an armature coil. The output-to-rotational speed characteristic, the input torque-to-rotational speed characteristic, and the like when the operation is performed can be appropriately changed.
[0060]
Generally, when the phase of the AC control voltage with respect to the induced voltage of the armature coil is changed to the leading side, the output of the rotating electrical machine as a generator can be reduced, and the charging current of the battery can be reduced. , The output as a generator can be increased, and the charging current of the battery can be increased.
[0061]
Therefore, when the above-described drive control is performed, even when the rotational speed is equal to or less than the no-load rotational speed of the rotating electric machine, the phase of the control voltage with respect to the induced voltage of the armature coil is changed to the lag side, whereby the armature is changed. The charging current can be supplied from the coil to the battery, and when the rotation speed exceeds the no-load rotation speed and the voltage of the battery exceeds the target value, the phase of the control voltage with respect to the induced voltage of the armature coil advances. By changing to the side, the charging current of the battery can be suppressed, and overcharging of the battery can be prevented.
[0062]
The drive control described above is already known as disclosed in Japanese Patent Application Laid-Open No. 11-46456.
[0063]
In the chopper control, all the switching elements Qx, Qy and Qz constituting the lower side of the bridge of the inverter are turned on and off at the same time, thereby interrupting the current flowing through the armature coil and boosting the induced voltage of the armature coil. Control. If the voltage at both ends of the battery is low and the battery needs to be charged when the rotation speed is lower than the no-load rotation speed, the chopper control as described above will make the battery available even if the rotation speed is lower than the no-load rotation speed. Can be charged.
[0064]
Incidentally, the chopper control of the rotating electric machine is already known, for example, as disclosed in JP-A-59-35538.
[0065]
The short-circuit control forms the lower side of the bridge of the inverter when the voltage at both ends of the battery 4 exceeds the target value in a state where the rotation speed of the engine 1 exceeds the no-load rotation speed of the rotary electric machine 2. When the switching elements Qx, Qy and Qz are simultaneously turned on to short-circuit the terminals of the rotary electric machine 2 through these switching elements and one of the feedback diodes, and the voltage across the battery 4 becomes lower than the target value. The switching elements Qx, Qy, and Qz on the lower side of the inverter bridge are turned on and off according to the voltage across the battery so that the switching elements Qx, Qy, and Qz are turned off to release the short circuit between the terminals of the rotating electric machine. Control.
[0066]
By performing such control, it is possible to prevent an excessive voltage from being applied to the battery or an excessive charging current from flowing when the rotational speed exceeds the no-load rotational speed, and to prevent the voltage at both ends of the battery from being increased. Can be maintained at the target value.
[0067]
It is to be noted that a method of controlling the switch element constituting the inverter and adjusting the voltage applied to the battery from the generator through the rectifier circuit in the inverter is already known.
[0068]
The controller further includes various control means necessary for operating the engine, such as means for controlling the ignition timing of the engine and controlling the amount of fuel injected from an injector that supplies fuel for the engine. Since these means are the same as those of the prior art, description thereof will be omitted.
[0069]
In the hybrid motorcycle shown in FIG. 1, when starting the engine 1, the controller 7 controls the rotating electric machine 2 while keeping the electromagnetic clutch 14 in the off state when a start command is given by a key switch (not shown) or the like. The inverter 5 is controlled so as to operate as a starter motor.
[0070]
When the rotating electric machine 2 is operated as a starter motor, the output torque of the rotating electric machine 2 is, as shown by an arrow A in FIG. 4, a path of the rotating shaft 2A, the spur gear 11a, the spur gear 11b, the one-way clutch 12, and the crankshaft 1a. And transmitted to the engine crankshaft. Thereby, cranking of the engine is performed, and the engine is started.
[0071]
When the engine is started, the output torque of the rotating electric machine is amplified to the speed reduction ratio of the speed reducer 11 and transmitted to the crankshaft. It can be performed without hindrance.
[0072]
When the rotation speed of the rotating electric machine operating as a motor reaches the start completion speed, the electromagnetic clutch 14 is turned on by the electromagnetic clutch control routine of FIG. When the electromagnetic clutch 14 is turned on, the rotating shaft of the rotating electric machine 2 is connected to the power transmission mechanism 13 having a reduction ratio of 1: 1 through the electromagnetic clutch 14, so that the rotating speed of the rotating electric machine 2 is reduced by the rotation of the engine. It will be the same as the speed. At this time, the one-way clutch 12 cuts off transmission of power from the engine 1 to the speed reducer 11, so that power is not transmitted from the engine to the rotating shaft of the rotating electric machine through the first power transmission unit 10A. If the rotation speed of the rotating electric machine is equal to or less than the rotation speed given by the product of the rotation speed of the engine and the reduction ratio of the speed reducer 11, power is transmitted from the rotating electric machine 2 to the engine through the first power transmission unit 10A. Never.
[0073]
When the rotating electric machine 2 is operated as an electric motor in this state, as shown by an arrow B in FIG. 5, the output of the rotating electric machine 2 through the path of the rotating shaft 2 a-the electromagnetic clutch 14-the second power transmission unit 10 B-the crankshaft 1 a. The torque is transmitted to the crankshaft 1a of the engine 1, and the engine is assisted by the rotating electric machine. In this state, the drive wheels of the motorcycle are driven by both the engine 1 and the rotating electric machine 2.
[0074]
As described above, when the rotating electric machine 2 is operated as the motor for assisting the engine, the switching phase of the excitation phase of the rotating electric machine is changed by the output Hu, Hv of the position detector and the output phase of the position detector so as to increase the output torque of the rotating electric machine. It is preferable to perform a control advance angle control for advancing beyond the theoretical switching phase determined by the output of Hw.
[0075]
When the battery needs to be charged with the electromagnetic clutch turned on as described above, the output torque of the engine 1 is reduced by the second power transmission unit 10B and the electromagnetic clutch 14B as shown by an arrow C in FIG. Is transmitted to the rotating shaft 2a of the rotating electric machine 2 through the above, so that the engine 1 drives the rotating electric machine 2 and the rotating electric machine 2 is operated as a generator.
[0076]
As described above, when the rotating electric machine 2 is operated as a generator, the feedback diodes Du, Dv, Dw, Dx, Dy, and Dz in the inverter 5 from the armature coils Lu to Lw of the rotating electric machine 2 and the switch A charging current flows to the battery 4 through a circuit including the elements Qu, Qv, Qw, Qx, Qy, and Qz, and the battery 4 is charged. When the charging of the battery 4 is completed and the voltage at both ends of the battery 4 exceeds the target value and the voltage at both ends of the battery 4 exceeds the target value while the battery 4 is being charged, the controller 7 sets the The switch elements Qx to Qz on the lower side of the bridge are simultaneously turned on to perform short-circuit control for short-circuiting the output of the rotating electric machine, or to perform the drive control, thereby stopping or suppressing the charging of the battery 4, The overcharge of the battery 4 is prevented.
[0077]
In the above-described embodiment, the electromagnetic clutch control means is configured so that the electromagnetic clutch 14 is always turned on after the engine is started, but it is not necessary to operate the rotating electric machine as an electric motor to assist the engine. (For example, when the driving mode in which the assist of the engine by the rotating electric machine is stopped by the driver is selected), the electromagnetic clutch 14 is turned off while the engine does not need to operate the rotating electric machine as a generator, and When charging is required, the electromagnetic clutch control means may be configured to turn on the electromagnetic clutch 14 in order to operate the rotating electric machine as a generator. When the electromagnetic clutch is controlled in this way, the control of the inverter 5 for operating the rotating electric machine as the electric motor is ended when the start of the engine is completed.
[0078]
Further, when the rotating electric machine 2 is driven by the engine 1 and the rotating electric machine is operated as a generator, when the charging of the battery 4 is completed and the voltage across the both ends becomes equal to or higher than the target value (when the rotating electric machine 2 When it is no longer necessary to operate as a generator), the electromagnetic clutch 14 is turned off, and when the battery 4 is discharged and the voltage at both ends thereof becomes less than the target value, the electromagnetic clutch 14 is turned on to turn the rotating electric machine on. The electromagnetic clutch control unit may be configured to control the on / off of the electromagnetic clutch 14 according to the voltage between both ends of the battery 4 so as to operate as a generator. In the case of such a configuration, the voltage adjustment by the controller 7 can be omitted. In addition, while the electromagnetic clutch 14 is in the off state, the rotating electric machine can be disconnected from the engine 1, so that the load on the engine can be reduced and the acceleration performance can be improved.
[0079]
Further, when a situation requiring acceleration performance is detected in a rotation speed region in which the rotating electric machine is operated as a generator, the electromagnetic clutch 14 is turned off to reduce the load on the engine. The electromagnetic clutch control means may be configured to control the on / off of the electromagnetic clutch 14 in accordance with the above.
[0080]
In the example shown in FIG. 1, the one-way clutch 12 is provided on the engine side, but the power from the rotating electric machine side to the engine side is provided between the rotating electric machine 2 side, for example, between the rotating shaft 2a of the rotating electric machine and the spur gear 11a. May be provided.
[0081]
FIG. 7 shows a specific configuration example of the power transmission device 10 according to the present invention. In FIG. 7, reference numeral 20 denotes a frame to which a crankcase of an engine is connected. A mechanism cover 21 is fixed to the frame 20 by appropriate means, and a frame 20 and a mechanism cover 21 constitute a mechanism case 22 of a power transmission device. .
[0082]
The front end of the crankshaft 1 a is supported on the frame 20 via a bearing 23, and the front end of the crankshaft 1 is introduced into the mechanism case 22. The housing 24 of the rotating electric machine 2 is also mounted on the frame 20, and the tip of the rotating shaft 2 a of the rotating electric machine supported at the end of the housing 24 via a bearing 25 is introduced into the mechanism case 22 through the frame 20. I have.
[0083]
The small spur gear 11a is fixed to a portion of the rotary shaft 2a introduced into the mechanism case 22 near the frame 20, and the large spur gear 11b is connected to the crankshaft 1a via a bearing 26 at a portion of the crankshaft 1a near the frame 20. It is attached rotatably. The small spur gear 11a and the large spur gear 11b mesh with each other, and the spur gear constitutes a reduction gear 11 having a reduction ratio of 4: 1 as viewed from the rotating electric machine 2 side.
[0084]
A spur gear 13b is fixed to the tip of the crankshaft 1a, and the boss 11b1 of the spur gear 11b and the spur gear 13b are connected via a one-way clutch 12. The one-way clutch 12 is configured to transmit power only from the spur gear 11b to the spur gear 13b and not transmit power from the spur gear 13b to the spur gear 11b. As the one-way clutch 12, a known one can be used.
[0085]
A spur gear 13a having the same number of teeth as the spur gear 13b is attached to the tip of the rotating shaft 2a of the rotating electric machine via a bearing 27, and the spur gears 13a and 13b are engaged with each other to form a power transmission mechanism 13.
[0086]
A rotor 14a of an electromagnetic clutch is attached to the tip of the rotating shaft 2a in a state where it can slightly thrust, and an armature 14b fixed to an end face of the spur gear 13a is opposed to the rotor 14a. A stator core 14d around which an electromagnetic coil 14c is wound is fixed to an inner surface of the cover 21 facing the rotor 14a, and a magnetic pole formed on the stator core 14d faces the rotor 14a. The electromagnetic clutch 14 is constituted by the rotor 14a, the armature 14b, the electromagnetic coil 14c, and the stator core 14d.
[0087]
In this electromagnetic clutch, the rotor 14a is not attracted to the armature 14b when the electromagnetic coil 14c is in the non-excited state. At this time, the rotor 14a is not restrained by the armature 14b, and the electromagnetic clutch 14 is off. When the electromagnetic coil 14c is excited, the magnetic flux generated from the electromagnetic coil 14c flows through the stator core, the rotor 14a, and the armature 14b, so that the rotor 14a is attracted to the armature 14b, and the electromagnetic clutch 14 is turned on.
[0088]
In the power transmission device shown in FIG. 7, when the electromagnetic clutch 14 is in the off state, the transmission of power between the rotation shaft 2a and the gear 13a is interrupted, so that the rotation shaft 2a is connected to the second power transmission unit 10B. In a state of being disconnected from When the rotating electric machine 2 is operated as an electric motor in this state, the output torque is transmitted from the rotating shaft 2a to the crankshaft 1a through the gears 11a and 11b and the one-way clutch 12.
[0089]
When the electromagnetic clutch 14 is turned on, the rotating shaft 2a is coupled to the gear 13a, so that the output torque of the rotating electric machine 2 is transmitted to the crankshaft 1a through the second power transmission unit 10B.
[0090]
In the above-described embodiment, the reduction ratio of the power transmission mechanism of the second power transmission unit 10B as viewed from the rotating electric machine side is 1: 1. It is sufficient that the speed reduction ratio of the speed reducer of the power transmission unit is sufficiently smaller than 1: 1.
[0091]
【The invention's effect】
As described above, according to the present invention, the power transmission device provided between the rotating shaft of the rotating electric machine and the crankshaft of the engine is provided with a speed reducer for reducing the rotation of the rotating electric machine and a rotating electric machine from the rotating electric machine side to the crankshaft side. A first power transmission unit having a one-way clutch for transmitting power only, a power transmission mechanism having a reduction ratio as viewed from the rotating electric machine side smaller than a reduction ratio of the speed reducer of the first power transmission unit, and starting; The second power transmission unit that transmits power between the rotating shaft of the rotating electric machine and the crankshaft of the engine through an electromagnetic clutch that is sometimes kept in an off state, so that the first power transmission unit is decelerated. By setting the ratio sufficiently high, the engine can be started using a small rotating electric machine.
[0092]
Further, according to the present invention, after the engine is started, the electromagnetic clutch is turned on, and the rotation of the rotating electric machine is transmitted to the engine through the second power transmission unit having a reduction ratio smaller than that of the reduction gear of the first power transmission unit. Since the transmission can be performed, the engine can be assisted by operating the rotating electric machine as a motor, or the rotating electric machine can be operated as a generator to charge a battery with the output of the rotating electric machine.
[Brief description of the drawings]
FIG. 1 is a configuration diagram schematically showing a configuration of a hybrid motorcycle according to the present invention.
FIG. 2 is a circuit diagram showing a specific configuration example of the inverter shown in FIG.
FIG. 3 is a flowchart showing an algorithm of a task executed by a microprocessor of the controller shown in FIG. 1 to control an electromagnetic clutch.
FIG. 4 is an explanatory diagram illustrating a power transmission path when the rotating electric machine is operated as an engine starting motor in the hybrid vehicle shown in FIG. 1;
FIG. 5 is an explanatory diagram illustrating a power transmission path when the rotating electric machine is operated as an electric motor for engine assist in the hybrid vehicle shown in FIG.
FIG. 6 is an explanatory diagram illustrating a power transmission path when the rotating electric machine operates as a generator in the hybrid vehicle shown in FIG. 1;
FIG. 7 is a cross-sectional view showing a specific configuration example of a power transmission device used in the present invention.
FIG. 8 is a graph showing a rotational speed vs. output torque characteristic required for the rotating electric machine when starting the engine and assisting the engine.
FIG. 9 is a configuration diagram schematically showing a configuration of a previously proposed hybrid vehicle.
[Explanation of symbols]
1: engine, 2: rotating electric machine, 4: battery, 5: inverter, 7: controller, 10: power transmission device, 10A: first power transmission unit, 10B: second power transmission unit, 11: reduction gear, 12: one-way clutch, 13: power transmission mechanism, 14: electromagnetic clutch.

Claims (3)

An engine that drives the drive wheels of the motorcycle, a rotating electric machine that is also used as a generator and an electric motor, and a power transmission device provided between a crankshaft of the engine and a rotating shaft of the rotating electric machine, The rotating electric machine is operated as a starter motor that drives the crankshaft of the engine when the engine is started, and is operated as an assist motor that assists the engine as needed during operation of the motorcycle, and is mounted on the motorcycle. A hybrid motorcycle that is operated as a battery charging generator using the engine as a driving source when charging the battery,
The power transmission device,
A reduction gear that reduces the rotation of the rotating shaft of the rotating electric machine, and a one-way clutch that only performs transmission of power from the rotating electric machine side to the crankshaft side of the engine is provided. A first power transmission unit configured to transmit to the crankshaft of the engine through the speed reducer and the one-way clutch;
A second power transmission mechanism provided with a power transmission mechanism and an electromagnetic clutch for transmitting power between the rotating shaft of the rotary electric machine and the crankshaft of the engine through the power transmission mechanism and the electromagnetic clutch; Power transmission section,
A controller that controls the electromagnetic clutch so that the electromagnetic clutch is turned off when the engine is started, and the electromagnetic clutch is turned on if necessary after the engine is started;
The hybrid motorcycle, wherein the power transmission mechanism of the second power transmission unit is configured such that a reduction ratio viewed from the rotating electric machine side is smaller than a reduction ratio of the speed reducer of the first power transmission unit. The controller is configured to operate the rotating electric machine as a motor after the engine is started to assist the engine by operating the rotating electric machine, and to operate the rotating electric machine as a generator to charge a battery by an output of the generator. An electromagnetic clutch is turned on, and even when the engine is running, there is no need to assist the engine with the rotating electric machine, and when there is no need to charge a battery with the rotating electric machine, the electromagnetic clutch is turned off. The hybrid motorcycle according to claim 1, wherein the hybrid clutch is configured to control the electromagnetic clutch. An engine that drives the drive wheels of the motorcycle, and is operated as a starter motor that drives the crankshaft of the engine when the engine is started, and is operated as an assist motor that assists the engine as needed during the operation of the motorcycle. When charging a battery mounted on the motorcycle, the crankshaft of the engine and the rotating electric machine of a hybrid motorcycle including a rotating electric machine driven by the engine as a drive source and a generator for charging the battery. A power transmission device provided between the rotary shaft and
A reduction gear that reduces the rotation of the rotating shaft of the rotating electric machine, and a one-way clutch that only performs transmission of power from the rotating electric machine side to the crankshaft side of the engine is provided. A first power transmission unit configured to transmit to the crankshaft of the engine through the speed reducer and the one-way clutch;
A second power transmission unit configured to transmit power between a rotation shaft of the rotating electric machine and a crankshaft of the engine through a power transmission mechanism and an electromagnetic clutch,
The power transmission mechanism of the second power transmission unit is configured such that a reduction ratio viewed from the rotating electric machine side is smaller than a reduction ratio of the speed reducer of the first power transmission unit. Transmission device.

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