JP6069337B2 - Engine starter - Google Patents

Description

  The present invention relates to an engine starting device mounted on a vehicle such as a motorcycle, and more particularly to an engine starting device capable of efficiently starting an engine in a starting device having a cranking means by a cell motor or a kick operation.

When the battery has run out in a motorcycle, the power necessary for starting ignition of the engine cannot be supplied from the battery. In such a case, a kick start system is known that generates power by cranking means that steps down the kick pedal and rotates the crankshaft, and supplies the power to the ignition system to operate the ignition system and start the engine. It has been. When the engine is started, the electric power consumed by the ignition coil and ignition capacitor is large.
Therefore, in a kick start system, if a user with weak kicking force performs a kick operation, the engine cranking speed is low, and if the engine does not normally explode, the charge generated by the power generation is discharged every time. Even so, there was a phenomenon that the engine could not be started due to insufficient charge required for starting ignition.

  Therefore, as shown in Patent Document 1, for example, at the time of kick start, the kick operation is performed before the ignition switch is turned on to store the charge in the start capacitor, and then the kick operation is performed again after the ignition switch is turned on. Thus, an engine starting device is disclosed in which the engine is started by a single kick operation.

JP 2007-120377 A

  However, according to the above-described technique, whether or not to store charges in the starting capacitor in advance before cranking by the kick operation is left to the driver's ignition switch operation. Therefore, it was necessary for the driver to be familiar with how to use it. Furthermore, even though it was determined that the engine could be started with a single kick operation, the cranking speed was actually low and the engine could not be started, or conversely, the engine could be started with a single kick operation. If it is judged that the cranking speed is low and the charge is stored in the starting capacitor in advance, it is necessary to perform an operation that is not necessary, and a more efficient way to start the engine is desired. It was.

  The present invention has been proposed in view of the above circumstances, and an object of the present invention is to provide an engine starter that can perform a reliable and efficient engine start by eliminating a useless kick operation.

In order to achieve the above object, the present invention provides a crankshaft (11) constituting an engine, a generator (2) rotating in synchronization with the rotation of the crankshaft (11), and the generator (2). A spark plug (12) that uses the electric power of the spark to ignite a spark, an ignition coil (5) that supplies a high voltage to the spark plug (12), and the crankshaft (11) that rotates to start the engine An engine starter comprising: cranking means for switching; switching means (transistor 63) for performing on / off control of a voltage applied to the spark plug (12); and CPU (64) for controlling the switching means.
A storage capacitor (62) connected in parallel to the generator (2) with respect to the ignition coil (5),
The CPU (64) detects a monitor voltage between the storage capacitor (62) and the ignition coil (5), and switches the switching means (transistor 63) only when the monitor voltage becomes equal to or higher than a predetermined voltage. It is characterized by being in a conductive state.

Claim 2 utilizes the crankshaft (11) constituting the engine, the generator (2) rotating in synchronization with the rotation of the crankshaft (11), and the electric power from the generator (2). A spark plug (12) for blowing sparks, an ignition coil (5) for supplying a high voltage to the spark plug (12), and cranking means for rotating the crankshaft (11) to start the engine; In an engine starter comprising switching means (thyristor 72) for performing on / off control of a voltage applied to the spark plug (12), and a CPU (64) for controlling the switching means,
A storage capacitor (62) connected in parallel with the generator (2) with respect to the ignition coil (5);
An ignition high voltage generation circuit (69) is connected to the storage capacitor (62), and an ignition capacitor (70) is connected between the ignition high voltage generation circuit (69) and the ignition coil (5). ,
The CPU (64) detects a monitor voltage between the ignition capacitor (70) and the switching means (thyristor 72), and only when the monitor voltage exceeds a predetermined voltage, the switching means (thyristor 72). Is in a conductive state.

  According to a third aspect of the present invention, in the engine starting device according to the first or second aspect, the generator (2) is disposed between the power storage capacitor (62) and the power generator (2) from the power storage capacitor (62) side. The diode (61) which interrupts | blocks the electric current to the side is arrange | positioned, It is characterized by the above-mentioned.

  According to a fourth aspect of the present invention, the engine starter of the third aspect includes a battery (4) for storing electric power generated by the generator (2), wherein the battery (4) is upstream of the diode (61). It is characterized by being arranged on the side.

  According to a fifth aspect of the present invention, in the engine starting device according to any one of the first to fourth aspects, the power from the generator (2) is supplied to the CPU (64) upstream of the CPU (64). A CPU power supply (66) for supplying power is arranged, and a CPU power supply capacitor (67) for stabilizing the voltage to the CPU (64) is disposed between the CPU (64) and the CPU power supply (66). The storage capacitor (62) is arranged further upstream of the CPU power supply (66).

  According to a sixth aspect of the present invention, in the engine starting device according to the fourth or fifth aspect, the cranking means is a cell motor that is rotated by electric power supplied from the battery (4), and a rotational force of the cell motor is converted to the crankshaft ( 11) It is characterized by comprising a transmission device for transmission.

  A seventh aspect of the present invention is the engine starting device according to any one of the first to sixth aspects, wherein the cranking means transmits a kick pedal and a rotational force of the kick pedal to the crankshaft (11). It is characterized by comprising a transmission device.

  According to an eighth aspect of the present invention, in the engine starting device according to any one of the first to seventh aspects, the engine is mounted on a vehicle, and the cranking means includes a drive wheel and the drive wheel. It is characterized by comprising a transmission device for transmitting the rotational force to the crankshaft (11) when turning.

  According to the present invention, even when the crankshaft (11) is rotated by the cranking means and ignition of the spark plug (12) does not occur, the power is stored in the storage capacitor (62) without consuming the electric power. By performing the starting process only at the ignition timing when the electrical energy necessary for starting is stored, the engine can be easily started.

  In particular, according to the circuit configuration of claim 1, the transistor (63) can be used as switching means for performing on / off control of the voltage applied to the spark plug (12), and the storage capacitor (62) By detecting the monitor voltage between the ignition coils (5), a full-transistor engine starting device can be obtained.

  Further, according to the circuit configuration of claim 2, the thyristor (72) can be used as switching means for performing on / off control of the voltage applied to the spark plug (12), and an ignition high voltage generating circuit is connected to the storage capacitor (62). (69) and an ignition capacitor (70) connected between the ignition high voltage generation circuit (69) and the ignition coil (5). The CPU (64) and the ignition capacitor (70) are connected to the switching means. By detecting the monitor voltage between them, a CDI engine starting device can be obtained.

  By arranging the CPU power supply (66) and the CPU power supply capacitor (67), stable power can be supplied to the CPU (64). In addition to the CPU power supply capacitor (67), the CPU power supply (66) Since the storage capacitor (62) is arranged upstream, the power applied to the ignition coil (5) can be stored efficiently.

It is a block diagram which shows the structure of the principal part of the engine starting apparatus (full transistor type) which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the principal part of the engine starting apparatus (CDI type) which concerns on one Embodiment of this invention. It is a flowchart which shows the starting procedure of the engine by the engine starting apparatus of this invention.

Hereinafter, an engine starter of the present invention mounted on a vehicle such as a motorcycle will be described with reference to the drawings.
The ignition device included in the engine starter includes a full-transistor type in which the primary current of the ignition coil is cut off by the ignition transistor to cause a current change in the primary coil, and the charge accumulated in the capacitor is matched to the ignition timing. It is roughly divided into the CDI type that discharges to the primary coil. First, a full-transistor engine starter to which the present invention is applied is shown in FIG.

  The engine starter is connected to an engine (internal combustion engine) 1 and a crankshaft 11 of the engine (internal combustion engine) 1, and an AC generator 2 that rotates in synchronization with the rotation of the crankshaft 11 and an AC generator 2 are generated. A regulator 3 that outputs a DC voltage by half-wave rectifying an AC voltage to be output, a battery 4 to which a DC voltage output from the regulator 3 is supplied, and a spark plug 12 that is attached to the upper end of a cylinder 10 of the engine 1 An ignition coil 5 for supplying a high voltage and a full transistor type (dielectric discharge type) ignition unit 6 for controlling the voltage applied to the ignition coil 5 are provided.

The crankshaft 11 of the engine 1 is connected with a cranking means comprising a kick pedal or a starter motor (not shown) and a transmission device for transmitting the pedaling force of the kick pedal or the rotational force of the cell motor or the like to the crankshaft 11. The cranking means is configured such that the engine can be started by sliding the piston 13 in the cylinder 10 by rotating the crankshaft 11 by the depression force of the kick pedal or driving of the starter motor. Note that the cell motor is configured to rotate by electric power supplied from the battery 4.
When the engine 1 is mounted on a motorcycle, the cranking means is composed of, for example, drive wheels that are rear wheels and a transmission device that transmits the rotational force to the crankshaft 11 when the drive wheels are rotated.

  The spark plug 12 attached to the upper end of the cylinder 10 uses a voltage applied to the ignition coil 5 to cause a spark discharge in the cylinder 10 to ignite and burn a mixed gas of gasoline and air.

  The regulator 3 half-wave rectifies the AC voltage generated by the AC generator 2 and outputs a DC voltage. The DC voltage output from the regulator 3 is supplied for lighting the headlight 9 of the vehicle and charged in the battery 4 and is applied to the ignition unit 6 and the ignition coil 5 as a DC voltage of 12 to 15 volts.

The ignition coil 5 includes a primary coil 51 connected to the positive side of the battery 4 to which a DC voltage is applied, and a secondary coil connected to the positive side of the spark plug 12 and generating a voltage corresponding to a current change in the primary coil. 52.
Power supply to the primary coil 51 and interruption thereof are controlled by an ignition unit 6 described later. The secondary coil 52 is supplied with a high voltage generated according to the current change of the primary coil 51.

  The ignition unit 6 includes a diode 61 connected so that the direction of the ignition coil 5 from the battery 4 side is a forward direction, and a storage capacitor that serves as an ignition plug power source with one connected to the cathode side of the diode 61 and the other grounded 62, a transistor (switching means) 63 that performs on / off control of the current flowing through the primary coil 51, a CPU 64 that controls the conduction timing of the transistor (switching means) 63, and a DC voltage to the CPU 64 via the power line 65. It comprises a CPU power supply 66 to be supplied, a CPU power supply capacitor 67 for stabilizing the voltage to the CPU 64, and a voltage detection line 68 connected between the cathode side of the diode 61 and the storage capacitor 62 and the CPU.

  The storage capacitor 62 stores the electric charge generated in the AC generator 2 by the rotation of the crankshaft 11 when the cranking means is operated by the depression force of the kick pedal or the rotational force of the cell motor.

  The CPU power supply 66 is disposed on the upstream side of the CPU 64 (alternator 2 side) in order to supply the power from the AC generator 2 to the CPU 64. The storage capacitor 62 is disposed further upstream of the CPU power supply 66. The battery 4 is disposed upstream of the diode 61.

  The CPU power supply capacitor 67 is connected between the power supply line 65 and the ground, and keeps the power supply voltage supplied to the CPU 64 constant. The collector of the transistor (switching means) 63 is connected to the primary coil 51, and the emitter of the transistor 32 is grounded.

The CPU 64 detects the monitor voltage between the storage capacitor 62 and the primary coil 51 via the voltage detection line 68, and only when the monitor voltage exceeds a predetermined voltage set in advance, the gate of the transistor (switching means) 63 Is applied to the ON state, a current flows between the collector and emitter of the transistor 63 from the primary coil 51, a high voltage is generated in the secondary coil 52, and the spark plug 12 is ignited.
The diode 61 is for preventing current from flowing from the storage capacitor 62 side to the AC generator 2 side.

Next, an engine starter in which the present invention is applied to the CDI type that discharges the electric charge accumulated in the engine start capacitor to the primary coil in accordance with the ignition timing will be described with reference to FIG. In FIG. 2, parts having the same configuration as in FIG.
Further, the engine starter may be configured to start the engine only by a kick operation of a kick pedal connected to the cranking means without including the battery 4 that charges the electric power generated by the AC generator 2.

Between the regulator 3 and the ignition coil 5, an ignition high voltage generation circuit 69 that converts a DC voltage obtained by half-wave rectification of the AC voltage generated by the AC generator 2 into a high voltage, and an ignition capacitor that stores electric charge 70 is connected. The ignition high voltage generation circuit 69 includes a converter that boosts an input voltage to about 300 V and outputs the boosted voltage.
Between the primary coil 51 and the ground, a trigger circuit 71 controlled by the CPU 64 is connected with a thyristor 72 that is turned on by applying a pulse voltage to the gate.

  The CPU 64 detects the applied voltage of the ignition capacitor 70 applied to the primary coil 51 of the ignition coil 5 through the voltage detection line 68 as a monitor voltage, and when the monitor voltage becomes equal to or higher than a preset predetermined voltage, The trigger circuit 71 is controlled to output a trigger pulse to the gate of a thyristor (switching means) 72. The trigger pulse from the trigger circuit 71 causes the thyristor (switching means) 72 to be in a conducting (ignition) state, and the charge accumulated in the ignition capacitor 70 is discharged to the primary coil 51 in accordance with the ignition timing, and the secondary coil 52 is high. A voltage is generated and the spark plug 12 is ignited.

  The thyristor 72 has a current value that flows through the thyristor 72 when the electric charge accumulated in the ignition capacitor 70 flows to the primary coil 51 in accordance with the ignition timing and then the discharge of the ignition capacitor 70 is completed and the electric charge becomes zero. Is zero, so natural arc extinction is performed at this timing.

Next, the operation of the engine starter described in FIGS. 1 and 2 will be described with reference to the flowchart of FIG.
It is known that when the AC generator 2 generates power by the depression force of the kick pedal or the rotational force of the cell motor, most of the generated electric energy is consumed by the ignition coil 5. The transistor 63 (thyristor 72) as a switching means is turned on by the ignition signal from the CPU 64 and the ignition coil 5 is energized. However, as soon as a large current for ignition flows through the ignition coil 5, the storage capacitor 62 (ignition) The power supply voltage of the capacitor 70) decreases and the ignition unit 6 stops and a situation where ignition is impossible occurs.

According to the engine starting device described above, first, the crankshaft 11 is rotated by operating the cranking means by the depression force of the kick pedal or the rotational force of the cell motor (step 81).
The alternator 2 generates power by the rotation of the rotor of the alternator 2 connected to the crankshaft 11 (step 82).

The electric power generated by the AC generator 2 is stored in the storage capacitor 62 (step 83).
The CPU 64 detects the voltage (storage state) by the storage capacitor 62 via the voltage detection line 68 and determines whether or not it is equal to or higher than the specified voltage (step 84).

  If the voltage value is less than the specified voltage, step 81 to step 83 are repeated. That is, when there is no voltage (electrical energy) necessary for ignition in the storage capacitor 62, the energy is preserved without energizing the ignition coil 5, and the voltage of the storage capacitor 62 increases every time the kick pedal is kicked. To do.

  When the voltage value is equal to or higher than the specified voltage, the CPU 64 is activated to output a pulse signal to the gate of the transistor (switching means) 63, thereby turning on (step 85). That is, the CPU 64 can confirm that the voltage of the storage capacitor 62 has risen to a voltage necessary for ignition in the ignition coil 5 by the voltage detection line 68, and when the ignition timing comes, the transistor (switching means). 63 is turned on and ignition by the ignition coil 5 is performed.

When a current flows through the primary coil 51 of the ignition coil 5, a high voltage is applied to the secondary coil 52, and an ignition process by the spark plug 12 is executed (step 86).
Since the CPU 64 itself in the ignition unit 6 consumes less power and can be driven at a low voltage, once it is kicked, continuous operation is possible with the electric energy of the CPU power supply capacitor 67 for a long time.

  In the case of the CDI type engine starting device of FIG. 2, in step 83, the electric power generated by the AC generator 2 is stored in the storage capacitor 62, and the ignition high voltage generation circuit 69 outputs a high voltage corresponding to the storage voltage. The electricity is stored in the ignition capacitor 70. In step 84, the CPU 64 detects the voltage (charged state) by the ignition capacitor 70 via the voltage detection line 68, and determines whether or not the voltage is equal to or higher than the specified voltage. If the voltage value is equal to or higher than the specified voltage, the CPU 64 is activated to output a trigger pulse to the gate of the thyristor (switching means) 72, thereby turning on (step 85).

According to the engine starting device described above, even if a person who cannot step down the kick pedal strongly (low pedaling force) kicks several times, the storage capacitor 62 (FIG. 1) and the ignition capacitor 70 (FIG. 2) are required to start the engine. It is possible to store electrical energy. Therefore, since a high voltage can be reliably supplied to the primary coil 51 of the ignition coil 5, a large ignition energy can be supplied to the spark plug 12, and the engine can be reliably started.
Further, even in a small AC generator (AGC) unsuitable for kick start, since reliable kick start is possible, there is an advantage that the AGC can be reduced in size and weight.

  DESCRIPTION OF SYMBOLS 1 ... Engine, 2 ... Alternator, 3 ... Regulator, 4 ... Battery, 5 ... Ignition coil, 6 ... Ignition unit, 10 ... Cylinder, 11 ... Crankshaft, 12 ... Spark plug, 51 ... Primary coil, 52 ... Two Next coil 61: Diode, 62 ... Storage capacitor, 63 ... Transistor (switching means), 64 ... CPU, 65 ... Power supply line, 66 ... CPU power supply, 67 ... CPU power supply capacitor, 68 ... Voltage detection line, 69 ... Ignition high voltage Generating circuit, 70 ... ignition capacitor, 71 ... trigger circuit, 72 ... thyristor (switching means).

Claims (5)

A generator (2) that rotates in synchronization with the rotation of the crankshaft (11) of the engine, a spark plug (12) that uses electric power from the generator (2) to spark, and the spark plug (12 Ignition coil (5) for supplying a high voltage to the motor), cranking means for rotating the crankshaft (11) to start the engine, and on / off control of the voltage applied to the spark plug (12) In an engine starter comprising switching means (63) for performing the above and a CPU (64) for controlling the switching means,
A diode (61) for flowing the output of the generator (2) in the forward direction;
A storage capacitor (62) connected in parallel with the generator (2) to the ignition coil (5);
A CPU power supply (66) for supplying power to the power line (65) of the CPU based on the output of the generator (2) ;
A CPU power capacitor (67) having one end connected to the power line of the CPU and the other end grounded ;
The primary side of the ignition coil and the CPU power source (66) are connected to the cathode of the diode (61) together with one end of the storage capacitor (62),
The CPU (64) detects the monitor voltage between the storage capacitor (62) and the ignition coil (5), and conducts the switching means (63) only when the monitor voltage exceeds a predetermined voltage. An engine starter characterized by being in a state. It said generator (2) includes a battery (4) for storing electric power generated by said battery (4), the engine starting device of claim 1, which is connected to the anode side of the diode (61). 3. The engine starter according to claim 2 , wherein the cranking means includes a cell motor that is rotated by electric power supplied from the battery (4), and a transmission device that transmits the rotational force of the cell motor to the crankshaft (11). . The engine starter according to any one of claims 1 to 3 , wherein the cranking means includes a kick pedal and a transmission device that transmits a rotational force of the kick pedal to the crankshaft (11). The engine is mounted on a vehicle, and the cranking means includes a drive wheel and a transmission device that transmits the rotational force to the crankshaft (11) when the drive wheel is rotated. The engine starter according to any one of claims 1 to 4 .

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