Ignition timing and detonation controller for internal combustion engine ignition system
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02P-005/04
출원번호
US-0083839
(1979-10-11)
발명자
/ 주소
Staerzl, Richard E.
출원인 / 주소
Brunswick Corporation
인용정보
피인용 횟수 :
26인용 특허 :
4
초록▼
An internal combustion engine employs an alternator driven capacitor dishcarge ignition system wherein a stator coil assembly provides power pulses to charge the capacitors and an adjustably positionable coil assembly provides electrical pulses whose frequency and magnitude (bias voltage) are relate
An internal combustion engine employs an alternator driven capacitor dishcarge ignition system wherein a stator coil assembly provides power pulses to charge the capacitors and an adjustably positionable coil assembly provides electrical pulses whose frequency and magnitude (bias voltage) are related to engine speed and effect ignition timing i.e., capacitor discharge. An electronic solid state ignition timing and detonation controller is connected to the capacitor discharge ignition system and operates in response to the pulses from the high speed winding of the aforesaid stator coil assembly to supply a bias signal which reduces the aforesaid bias voltage from the said other coil assembly at higher engine speeds thereby providing additional spark advance, depending upon engine speed and detonation severity. The electronic controller improves engine efficiency at cruising speeds and reduces detonation at high speeds.
대표청구항▼
1. In an alternator driven capacitor discharge system for an internal combustion engine having capacitor means, and an alternator including first coil means for providing electrical pulses for charging said capacitor means, said electrical pulses having a frequency related to engine speed, and secon
1. In an alternator driven capacitor discharge system for an internal combustion engine having capacitor means, and an alternator including first coil means for providing electrical pulses for charging said capacitor means, said electrical pulses having a frequency related to engine speed, and second coil means for providing a biasing signal for regulating the timing of the discharge of said capacitor means and tending to effect timing advance as engine speed increases, the improvement comprising: means responsive to the frequency of said electrical pulses for modifying said biasing signal so as to effect additional timing advance when engine speed exceeds a predetermined speed, said means responsive to the frequency of said electrical pulses including advance timer means which operates to effect timing advance in proportion to the increase in engine speed above said predetermined speed until a second predetermined speed is reached, and retard timer means which operates to effect a reduction in timing advance in proportion to the increase in engine speed above said second predetermined speed until engine speed returns to said second predetermined speed; and means responsive to engine detonation for further modifying said biasing signal so as to effect a reduction of said additional timing advance when detonation exceeds a predetermined level. 2. A system according to claim 1 wherein said advance timer means and said retard timer means each include a monostable multivibrator which provides a pulsed output signal having a predetermined pulse width, and wherein said advance timer means effects timing advance when the period of said pulses from said first coil means equals said predetermined pulse width and until said period reaches half said predetermined pulse width, and wherein said retard timer means effects timing retard when the period of said pulses from said first coil means equals said predetermined pulse width and until said period reaches half said predetermined pulse width. 3. In an alternator drive capacitor discharge system for an internal combustion engine having capacitor means, and an alternator including first coil means for providing electrical pulses for charging said capacitor means, said electrical pulses having a frequency related to engine speed, and second coil means for providing a biasing signal for regulating the timing of the discharge of said capacitor means and tending to effect timing advance as engine speed increases, the improvement comprising: means responsive to the frequency of said electrical pulses for modifying said biasing signal so as to effect additional timing advance when engine speed exceeds a predetermined speed, said means responsive to the frequency of said electrical pulses including a phase-shifting circuit for providing phase-shifted signals based on said pulses, an advance timer circuit and a retard timer circuit for receiving said phase-shifted signals and for providing timer output signals based therein, a control gate circuit for receiving said timer output signals and for providing a gate signal based thereon, and an ignition bias control circuit for receiving said gate signal and a timer output signal from said retard timer and for providing a bias control signal for modifying said biasing signal; and means responsive to engine detonation for further modifying said biasing signal so as to effect a reduction of said additional timing advance when detonation exceeds a predetermined level. 4. A system according to claim 3 wherein said means responsive to engine detonation provides a detonation signal to said ignition bias control circuit to modify said bias control signal therefrom. 5. A system according to claim 4 wherein said detonation signal reduces said bias control signal in proportion to increases in engine detonation. 6. A system according to claim 5 wherein said means responsive to engine detonation is further responsive to the timer output signal of said retard timer circuit so that said detonation signal must increase in value in order to effect reduction of spark advance, thereby preventing high speed engine noise from effecting production of a spurious detonation signal by said means responsive to engine detonation. 7. In an alternator driven capacitor discharge system for an internal combustion engine having capacitor means, and an alternator including first coil means for providing electrical pulses for charging said capacitor means, said electrical pulses having a frequency related to engine speed, and second coil means for providing a biasing signal to a first timing circuit for regulating the timing of the discharge of said capacitor means and tending to effect timing advance as engine speed increases, the improvement comprising: first means responsive to the frequency of said electrical pulses from said first coil means to provide a bias voltage to said first timing circuit to modify said biasing signal so as to effect additional timing advance when engine speed exceeds a predetermined speed; and second means responsive to engine detonation for providing a control signal to modify said bias voltage so as to effect a reduction of said additional timing advance when detonation exceeds a predetermined level; said first means comprising: an ignition bias control circuit for applying said bias voltage to said first timing circuit, a phase shifter circuit for receiving said electrical pulses from said first coil means and for providing a pair of phase-shifted pulsed signals; an advance timer circuit and a retard timer circuit for operating said ignition bias control circuit, each advance and retard timer circuit including a monostable multivibrator, and each advance and retard timer circuit receiving said pair of phase-shifted pulsed signals, each advance and retard timer circuit providing timer output signals for operating said ignition bias control circuit to cause the latter to advance or retard timing, said advance timer circuit operating to initiate an advance timer output signal in proportion to engine speed increase when the period of said electrical pulses from said first coil means equals the pulse width of the signals of said advance monostable multivibrator and until said period reaches half said pulse width and maximum spark advance occurs; said retard timer circuit operating to initiate a retard timer output signal in proportion to further engine speed increase when the period of said electrical pulses from said first coil means equals the pulse width of the signals of said retard monostable multivibrator and until said period reaches half said pulse width and spark advance has returned to its initial starting point; said second means comprising: a detonation sensing circuit for providing said control signal to said ignition bias control circuit for reducing said bias voltage from said ignition bias control circuit in proportion to increases in engine detonation sensed thereby; said detonation sensing circuit being responsive to the timer output signal of said retard timer circuit so that said control signal must increase in value in order to effect reduction of spark advance, thereby preventing high speed noise of said engine from effecting production of a spurious control signal by said detonation sensing circuit. 8. An ignition timing and detonation controller for use in an alternator driven capacitor discharge system for an internal combustion engine which comprises capacitor means, and an alternator including first coil means for providing electrical pulses for charging said capacitor means, said pulses having a frequency related to engine speed, and second coil means for providing a bias signal for regulating the timing of the discharge of said capacitor means, said biasing signal tending to effect timing advance as engine speed increases; said controller comprising: a spark advance circuit; and a detonation sensing circuit; said spark advance circuit comprising a spark advance timer to improve engine efficiency at cruising speed and a retard timer to insure proper high speed operation of said ignition system and said detonation sensing circuit; said timers being triggered by a trigger pulse representative of engine speed; said controller operating so that spark advance is initiated when the duty cycle of said advance timer is equal to the period of said trigger pulse; said spark advance remaining proportional to engine speed until the duty cycle of said advance timer is double the period of said trigger pulse, whereupon maximum spark advance is reached; said controller further operating so that further increase in engine speed produces no change in spark timing until the duty cycle of said retard timer is equal to the period of said trigger pulse, whereupon an increase in engine speed produces a proportional decrease in spark advance until the duty cycle of said retard timer is double that of the period of the trigger pulse whereupon spark timing is back to where spark advance was initiated and a further increase in engine speed produces no further change in spark timing; said detonation sensing circuit operating to proportionally reduce the spark advance towards the initial timing in direct proportion to the amplitude of detonation. 9. A controller according to claim 8 wherein said detonation sensing circuit is connected to receive a signal from said spark advance circuit to gradually increase the threshold voltage needed to activate said detonation circuit and thereby inhibit high speed engine noise from actuating said detonation circuit. 10. A controller according to claim 9 wherein said detonation circuit is connected to receive said signal from said retard timer.
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이 특허에 인용된 특허 (4)
Douaud ; Andre ; Rialan ; Joseph, Device for optimum control of the sparking time of a spark ignition engine, during its operation.
Beikmann, Randall S., System and method for controlling a firing sequence of an engine to reduce vibration when cylinders of the engine are deactivated.
Brennan, Daniel G.; Naik, Sanjeev M., System and method for controlling spark timing when cylinders of an engine are deactivated to reduce noise and vibration.
Phillips, Andrew W., System and method for randomly adjusting a firing frequency of an engine to reduce vibration when cylinders of the engine are deactivated.
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