JP2015033913A - Hybrid system and control method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hybrid system that performs cranking of an engine by a motor generator through a continuously variable transmission mechanism, and a control method thereof.SOLUTION: In a hybrid system 1 having an engine 10 and a motor generator 21, a crank shaft 15 of an engine body 11 and the motor generator 21 are connected through a CVT 16. When there occurs a request for starting the engine 10, the motor generator 21 is rotationally driven, and after the diameter of a first pulley 16a of the CVT 16 is maximized and the diameter of a second pulley 16b is minimized, the motor generator 21 is rotationally driven, and cranking of the engine body 11 is performed.

Description

  The present invention relates to a hybrid system and a control method therefor, and more particularly to a hybrid system that cranks an engine with a motor generator via a continuously variable transmission mechanism and a control method therefor.

  Generally, the internal combustion engine is started by cranking the internal combustion engine using a starter. Since the internal combustion engine cannot expect the inertia of the flywheel when the rotational speed is zero, the lower the rotational speed of the crankshaft at the start, the larger the torque is required. Therefore, as the starter motor used for this starter, a DC direct winding motor with a brush having a characteristic of generating a maximum torque when the rotational speed is zero is suitably employed (see, for example, Patent Document 1).

  By the way, a brushless induction motor and a synchronous motor are adopted for the motor generator in the hybrid system. These motors have a characteristic that a constant torque is generated from a rotational speed of zero to a predetermined value.

  For this reason, cranking an internal combustion engine using such an induction motor or the like generates a surplus torque larger than that required for a DC direct-winding motor with a brush for the torque required for cranking. There is a problem that the battery for supplying the battery is wasted and its life is shortened.

JP-A-5-71450

  An object of the present invention is to provide a hybrid system for cranking an engine with a motor generator via a continuously variable transmission mechanism and a control method therefor.

  The hybrid system of the present invention that achieves the above object is a hybrid system having an internal combustion engine and a motor generator, and is directly connected to the crankshaft of the internal combustion engine and transmits the power of the internal combustion engine to the motor generator. A continuously variable transmission mechanism and control means for controlling the hybrid system are provided, and the control means drives the motor generator to rotate when a request for starting the internal combustion engine is generated, and from the motor generator The continuously variable transmission mechanism is controlled so that the torque transmitted to the crankshaft is maximized, and then the internal combustion engine is cranked using the motor generator.

The control method of the hybrid system of the present invention that achieves the above object includes an internal combustion engine and a motor generator, and the internal combustion engine is connected to the internal combustion engine via a continuously variable transmission mechanism that is directly connected to a crankshaft of the internal combustion engine. In a control method of a hybrid system for transmitting power to an engine,
When a request for starting the internal combustion engine is generated, the continuously variable transmission mechanism is controlled so that the transmission torque from the motor generator to the crankshaft is maximized, and then the internal combustion engine is controlled using the motor generator. It is characterized by cranking.

  According to the hybrid system and its control method of the present invention, the crankshaft of the internal combustion engine and the motor generator are connected via the continuously variable transmission mechanism so that the crankshaft side is in a high torque state when the internal combustion engine is started. Since the cranking is performed after controlling the continuously variable transmission mechanism, it is possible to provide a hybrid system in which the engine is cranked by the motor generator via the continuously variable transmission mechanism and the control method thereof.

  Further, since the torque of the motor generator that cranks the internal combustion engine is suppressed, it is possible to extend the life of the battery that supplies power to the motor generator.

It is a figure which shows the structure of the hybrid system which consists of embodiment of this invention. It is a flowchart explaining the control method of the hybrid system which consists of embodiment of this invention.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a hybrid system according to an embodiment of the present invention.

  The hybrid system 1 of this embodiment includes an engine (internal combustion engine) 10 and a motor generator (M / G) 21. Here, the hybrid system 1 is described as being mounted on a hybrid vehicle (HEV: hereinafter referred to as a vehicle) 2, but is not necessarily limited.

  The hybrid system 1 includes an engine 10, an exhaust passage 12, a turbocharger 13, and an exhaust gas purification device (post-treatment device) 14 provided in the exhaust passage 12.

  A CVT (continuously variable transmission mechanism: variable ratio mechanism) 16 is provided connected to the crankshaft 15 of the engine body 11, and a motor generator 21 is connected to the CVT 16. That is, the first pulley (first power transmission unit) 16a of the CVT 16 is directly connected to the crankshaft 15 of the engine 10, and the second pulley (second power transmission unit) 16b of the CVT 16 is provided to the motor generator 21. The power transmission between the crankshaft 15 and the motor generator 21 is performed via the first pulley 16a and the second pulley 16b.

  An endless belt or chain (power transmission member) 16c is hung between the first pulley 16a and the second pulley 16b, and the first pulley 16a, the power transmission member 16c and the first pulley 16a are connected to the first pulley 16a and the second pulley 16b. Power is transmitted to the motor generator 21 via the two pulleys 16b, and conversely, from the motor generator 21 to the crankshaft 15 via the second pulley 16b, the power transmission member 16c, and the first pulley 16a. The

  In this CVT 16, the widths of the first pulley 16a and the second pulley 16b are changed to change the radial position where the pulleys 16a, 16b and the power transmission member 16c are in contact, and the position where the power transmission member 16c is in contact The pulley diameter is reduced when the inner side becomes the inner side, and the pulley diameter is increased when the outer side becomes the outer side. And, by controlling the width of the two pulleys 16a and 16b to be opposite to each other by hydraulic or electric mechanism (not shown) by electronic control, the power transmission member 16c is not slackened. Shifting can be performed continuously.

  The motor generator 21 that is a part of the power system 20 generates power by receiving the driving force of the engine 10 as a generator, or generates regenerative power by generating regenerative power such as braking force of the vehicle 2, It drives as a motor, transmits the driving force to the crankshaft 15 of the engine 10, and assists the driving force of the engine 10.

  The electric power generated by the power generation is converted by the inverter (INV) 23 via the wiring 22 and charged in the first battery (charger: B1) 24A. When driving the motor generator 21, the electric power charged in the first battery 24 </ b> A is converted by the inverter 23 and supplied to the motor generator 21.

  In the configuration of FIG. 1, a DC-DC converter (CON) 25 and a second battery (B2) 24B are further provided in series with the first battery 24A. In the DC-DC converter 25, for example, the voltage is dropped to 12 V and charged to the second battery 24B, and the auxiliary battery cooling fan 26A, cooling water pump 26B, Electric power is supplied to the lubricating oil pump 26C and the like.

  In the vehicle 2 equipped with the hybrid system 1, the power of the engine 10 is transmitted to a transmission (transmission) 31 of the power transmission system 30, and is further actuated from the transmission 31 via a propulsion shaft (propeller shaft) 32. (Differential gear) 33, and is transmitted from the actuator 33 to the wheel 35 via a drive shaft 34. Thereby, the motive power of the engine 10 is transmitted to the wheels 35 and the vehicle 2 travels. Depending on the mounting method of the engine 10, the transmission path from the engine 10 to the wheel 35 may be different.

  On the other hand, regarding the power of the motor generator 21, the power charged in the first battery 24A is supplied to the motor generator 21 via the inverter 23, and the motor generator 21 is driven by this power to generate power. The power of the motor generator 21 is transmitted to the crankshaft 15 via the CVT 16, transmitted through the power transmission path of the engine 10, and transmitted to the wheels 35.

  Thereby, the power of the motor generator 21 is transmitted to the wheels 35 together with the power of the engine 10, and the vehicle 2 travels. During regeneration, the regenerative power of the wheels 35 or the regenerative power of the engine 10 is transmitted to the motor generator 21 through the reverse path, so that the motor generator 21 can generate power.

  Also, a hybrid system control device 41 is provided, and the operating state such as the rotational speed Ne and the load Q of the engine 10, the operating state such as the rotational speed Na of the motor generator 21, and the charging of the first battery 24A and the second battery 24B. The CVT 16, the motor generator 21, the inverter 23, the DC-DC converter 25, and the like are controlled while monitoring the capacity (SOC) state. The hybrid system control device 41 is usually configured to be incorporated in an overall control device 40 that controls the engine 10 and the vehicle 2. The overall control device 40 controls the combustion in the cylinder, the turbocharger 13, the exhaust gas purification device 14, the cooling fan 26A of the auxiliary machine, the cooling water pump 26B, the lubricating oil pump 26C and the like in the control of the engine 10. Yes.

  A control method in the vehicle 2 equipped with such a hybrid system 1 will be described below with reference to FIG.

  The hybrid system control device 41 determines whether a start request for the engine body 11 (including a restart request at idling stop) has been issued (S10), and when the start request is issued, the first battery 24A is charged. The motor generator 21 is rotationally driven by supplying the generated electric power (S20), the pulley diameter of the first pulley 16a is maximized, and the pulley diameter of the second pulley 16b is minimized (S30). Cranking is started by starting 15 rotations (S40).

  By performing such control, the crankshaft 15 is in a high torque and low rotation state, so that the torque generated by the motor generator 21 can be suppressed and the life of the first battery 24A can be extended.

  In the above control method, immediately after the crankshaft 15 starts rotating (S40), the ratio of the pulley diameter of the second pulley 16b to the pulley diameter of the first pulley 16a is continuously reduced (S50). desirable. Specifically, control is performed to continuously reduce the pulley diameter of the first pulley 16a and continuously increase the pulley diameter of the second pulley 16b.

  By doing so, since the crankshaft 15 continuously shifts to a high rotation and low torque state, the time for the crankshaft 15 to reach the rotational speed necessary for cranking the engine body 11 is shortened. The engine body 11 can be started early and smoothly.

  Instead of continuously reducing the ratio of the pulley diameter of the second pulley 16b to the pulley diameter of the first pulley 16a, the electric power supplied from the first battery 24A to the motor generator 21 is controlled to control the motor generator 21. Thus, the crankshaft 15 can be continuously shifted to a state of high rotation and low torque.

DESCRIPTION OF SYMBOLS 1 Hybrid system 2 Hybrid vehicle 10 Engine 11 Engine main body 15 Crankshaft 16 CVT
16a First pulley 16b Second pulley 21 Motor generator 24A First battery 41 Control device for hybrid system

Claims (4)

In a hybrid system having an internal combustion engine and a motor generator,
A continuously variable transmission mechanism that is directly connected to the crankshaft of the internal combustion engine and transmits the power of the internal combustion engine to the motor generator; and a control unit that controls the hybrid system;
The control means rotates the motor generator when a request for starting the internal combustion engine is generated, and controls the continuously variable transmission mechanism so that the transmission torque from the motor generator to the crankshaft is maximized. A hybrid system comprising: cranking the internal combustion engine using the motor generator after the control.   The control means controls the continuously variable transmission mechanism such that the transmission torque continuously decreases after controlling the continuously variable transmission mechanism so that the transmission torque from the motor generator to the crankshaft is maximized. The hybrid system according to claim 1 to be controlled.   2. The control unit according to claim 1, wherein the control unit continuously decreases the torque of the motor generator after controlling the continuously variable transmission mechanism so that a transmission torque from the motor generator to the crankshaft is maximized. Hybrid system. In a control method of a hybrid system having an internal combustion engine and a motor generator, and transmitting power from the motor generator to the internal combustion engine via a continuously variable transmission mechanism directly connected to a crankshaft of the internal combustion engine,
When a request for starting the internal combustion engine is generated, the continuously variable transmission mechanism is controlled so that the transmission torque from the motor generator to the crankshaft is maximized, and then the internal combustion engine is controlled using the motor generator. A control method of a hybrid system characterized by cranking.

Images