1. Field of the Invention
The present invention relates to an internal combustion engine ignition device, for example, mounted on a vehicle, and particularly to an internal combustion engine ignition device that generates an ignition high voltage across the secondary coil of an ignition coil, by flowing and interrupting an electric current for the primary coil of the ignition coil by use of a switching element.
2. Description of the Related Art
In a conventional internal combustion engine ignition device, an ion signal and an ignition signal are multiplexed and outputted on a coil-driver input signal line, and in the case where the ion signal is outputted, masking is performed so that the switching element does not turn on (for example, refer to Japanese Patent Laid-Open Pub. No. 2004-156608, Pages 17 and 18,
In the conventional internal combustion engine ignition device, there has been a problem that, in the case where, when the ion signal and the ignition signal are outputted at the coil-driver input signal line, the inside of the engine compartment becomes high-temperature, thereby causing pre-ignition, or a smolder occurs around the ignition plug, thereby producing soot between the electrodes, causing a leakage electric current to flow, and causing a pseudo ion current to flow constantly, it is required that the dynamic range of the input voltage be set wide in order to detect the ion current even at the timing when the ignition signal is supplied; as a result, the circuit scale of the ECU (Electronic Control Unit) becomes large, thereby causing the cost hike.
Moreover, there has been a problem that, in the case where a certain factor such as interruption of the primary-coil current causes a difference between the ground potential for the ECU and the ground potential for the coil driver, the ion signal cannot accurately be transferred to the ECU.
The present invention has been implemented in order to solve the foregoing problems; the objective of the present invention is to provide an internal combustion engine ignition device that can securely detect the ion current even at the timing when the ignition signal is supplied and that improves the functionality of the ignition system by enlarging at low cost the region in which the ion current can be detected.
An internal combustion engine ignition device according to the present invention includes an ignition coil having a primary coil and a secondary coil and a switching element that generates an ignition high voltage across the secondary coil of the ignition coil by flowing and interrupting a primary-coil current of the ignition coil; the internal combustion engine ignition device further includes an ECU (electronic control unit) including a pulse generation circuit that supplies a coil-driver input signal line with a single pulse signal having an extremely short duration or a plurality of pulse signals, as an energization start signal Igt1 or a de-energization signal Igt2; a pulse detection circuit that stores the energization start signal and the de-energization signal, that recognizes the single pulse signal or the plurality of pulse signals, received by way of the coil-driver input signal line from the pulse generation circuit, as the energization start signal or the de-energization signal, and that supplies an ignition signal to the switching element; an ion bias circuit that is connected to a low-voltage side of the secondary coil and generates an ion current; an ion-current detection circuit that detects an ion current flowing through the secondary coil; an ion-current output circuit that outputs an ion signal at the coil-driver input signal line, based on an output signal of the ion-current detection circuit; and an ion-signal detection/control circuit that is included in the ECU and that detects and controls an output signal of the ion-current output circuit. The internal combustion engine ignition device is configured in such a way that, at a timing when the pulse generation circuit outputs neither the energization start signal nor the de-energization signal, the ion-signal detection/control circuit sets an input voltage Igt of a coil driver to a high level, and at a timing when the pulse generation circuit outputs the energization start signal or the de-energization signal, the input voltage Igt of the coil driver is lowered for an extremely short time from the high level to a low level, so that the pulse detection circuit recognizes the change in the input voltage Igt as the energization start signal or the de-energization signal and supplies an ignition signal to the switching element, and in such a way that, at a timing except the timing when the energization start signal and the de-energization signal is supplied to the pulse detection circuit, the ion-current output circuit outputs an ion signal at the coil-driver input signal line, based on an ion current detected by the ion-current detection circuit.
According to the present invention, an internal combustion engine ignition device can be obtained in which, even in the case where the ignition signal is supplied when, the inside of the engine compartment becomes high-temperature, thereby causing pre-ignition, or a smolder around the ignition plug causes soot or the like in the space between the electrodes, thereby causing a leakage electric current to flow, whereby a pseudo ion current always flows, it is not required to make the dynamic range of the input voltage Igt wide, an ion current can accurately be detected by a 5-Volt system, and, at low cost, an ion-current detection region is enlarged and the functionality of the ignition system is enhanced.
Moreover, at the timing when the pulse generation circuit outputs neither the energization start signal nor the de-energization signal, the input voltage Igt of the coil driver is set to a high level (from 5 V to 14 V), so that the ion signal can accurately be transferred to the ECU, even in the case where a difference between the ground potential for the ECU and the ground potential for the coil driver is caused, for example, at the timing of interruption of the primary-coil current.
The foregoing and other object, features, aspects, and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
Embodiments of the present invention will be explained below with reference to the accompanying drawings.
As illustrated in
The internal combustion engine ignition device is configured in such a way that, at the timing when the pulse generation circuit 201 outputs neither the energization start signal Igt1 nor the de-energization signal Igt2, the ion-signal detection/control circuit 300 inside the ECU sets an input voltage Igt of the coil driver 400 to a high level (from 5 V to 14 V), and at the timing when the pulse generation circuit 201 outputs the energization start signal Igt1 or the de-energization signal Igt2, the ion-signal detection/control circuit 300 lowers for an extremely short time the input voltage Igt of the coil driver 400 from the high level (from 5 V to 14 V) to a low level (0 V), so that the pulse detection circuit 7 recognizes the change in the input voltage Igt as the energization start signal Igt1 or the de-energization signal Igt2 and supplies an ignition signal to the switching element 5, thereby driving the switching element 5.
The pulse detection circuit 7 is a circuit in which the energization start signal Igt1 and the de-energization signal Igt2 are stored.
The ion bias circuit 8 is a bias circuit for making an ion current flow. The ion-current detection circuit 9 supplies the ion-current-output current mirror circuit 10 with an ion current. The ion-current detection circuit 9 is activated at the timing when an ion current flows, and then the ion-current-output current mirror circuit 10 is activated. The ion-current-output current mirror circuit 10 extracts an electric current equivalent to the ion current from the ECU 200. In addition, the input voltage Igt of the coil driver 400 at this timing is given by the following equation:
Igt≈the voltage of the internal power source of the ECU 200−(ION×the resistance value of a resistor 203)
As a result, the ion-signal detection/control circuit 300 is activated, and the ion current is transferred to the ion-signal detection/control circuit 300.
By performing an analysis based on the ion current, the in-cylinder combustion condition is ascertained.
Next, the internal combustion engine ignition device according to Embodiment 1 will be described more specifically, with reference to
As illustrated in
At the timing when neither the energization start signal Igt1 nor the de-energization signal Igt2 is supplied to the NPN transistor 202 and the P-channel MOSFET 302, the input voltage Igt of the coil driver 400 is set to a high level (from 5 V to 14 V), and at the timing when the pulse generation circuit 201 supplies the energization start signal Igt1 or the de-energization signal Igt2 to the NPN transistor 202 and the P-channel MOSFET 302, the NPN transistor 202 turns on and the P-channel MOSFET 302 turns off, thereby lowering for an extremely short time the input voltage Igt of the coil driver 400 from the high level (from 5 V to 14 V) to a low level (0 V), so that a signal is supplied to the pulse detection circuit 7.
The pulse detection circuit 7 is a circuit in which the energization start signal Igt1 and the de-energization signal Igt2 are stored; the pulse detection circuit 7 recognizes the signal received from the pulse generation circuit 201 as the energization start signal Igt1 or the de-energization signal Igt2 and supplies an ignition signal to the switching element 5 in the later stage, thereby driving the switching element 5.
The switching element 5 is, for example, an IGBT (insulated gate bipolar transistor (IGBT); the gate terminal is connected to the pulse detection circuit 7, the collector terminal is connected to the primary coil 2 of the ignition coil 1, and the emitter terminal is connected to the reference potential point GND. The ion bias circuit 8 is connected to the low-voltage side of the secondary coil 3.
The ion bias circuit 8 is configured in such a way as to have an output terminal 8a and an input terminal 8b. The output terminal 8a is connected to the ion-current detection circuit 9 in the later stage, and the input terminal 8b is connected to the low-voltage side of the secondary coil 3.
The ion-current detection circuit 9 is connected to the ion-current-output current mirror circuit 10 and the ion bias circuit 8.
The ion-current-output current mirror circuit 10 is configured in such a way as to have an output terminal 10a and an input terminal 10b. The output terminal 10a is connected to the input impedance 6 and the pulse detection circuit 7, and the input terminal 10b is connected to the ion-current detection circuit 9.
Next, the inner configuration of the ion-signal detection/control circuit 300 will be explained. The ion-signal detection/control circuit 300 is configured with an internal power source 301, the P-channel MOSFET 302, a current mirror circuit 305 including PNP transistors 303 and 304, ion-current detection resistor 306, and an ion-signal control circuit 309. The gate of the P-channel MOSFET 302 in the ion-signal detection/control circuit 300 is connected to the pulse generation circuit 201; the drain is connected to the emitters of the PNP transistors 303 and 304; the source is connected to the internal power source 301. The internal power source 301 is a stabilized power source. The base of the PNP transistor 303 is connected to the base of the PNP transistor 304, and the collector of the PNP transistor 303 is connected to the ion-current detection resistor 306 and the ion-signal control circuit 309. The base of the PNP transistor 304 is connected to the collector of the PNP transistor 304 and the resistor 203. The other terminal of the ion-current detection resistor 306 is connected to the ground GND.
After that, during the time period between the time points t3 and t4, the pulse generation circuit 201 supplies the NPN transistor 202 and the P-channel MOSFET 302 with the de-energization signal Igt2 (here, represented as a single pulse) having an extremely short duration. The pulse detection circuit 7 recognizes the pulse signal received from the pulse generation circuit 201 as the de-energization signal Igt2 and, at the time point t4, interrupts the ignition signal that has been supplied to the switching element 5 in the later stage. At the time point t4 when, due to the interruption of the voltage supply to the input terminal (here, the gate) of the switching element 5, the switching element 5 turns off, the primary-coil current I1 flowing in the primary coil 2 is interrupted, whereby a high voltage is generated at the collector (here, represented as C) of the switching element 5.
The energy is converted through the secondary coil 3, whereby a negative voltage is induced at the high-voltage side of the secondary coil 3. On that occasion, a high voltage is applied to the low-voltage side of the secondary coil and a voltage is applied across a Zener diode 83 through a diode 81, whereby a capacitor 84 is charged. In the case where the negative voltage, which is large enough to break the insulation in the gap of the ignition plug 4, is generated, a discharge takes place, and, after the time point t4, a secondary-coil current flows from the ignition plug 4 to the ground GND by way of the secondary coil 3, the diode 81, and the Zener diode 83.
At the time instant t5 when the discharge is completed, the voltage charged across the capacitor 84 causes an ion current to start to flow through the secondary coil 3 by the intermediary of a resistor 82. The ion-current detection circuit 9 is activated at this time instant, and then the ion-current-output current mirror circuit 10 is activated. An N-channel MOSFET 101 in the ion-current-output current mirror circuit 10 extracts a drain current, corresponding to the ion current that flows through an N-channel MOSFET 102, from the current mirror circuit 305 in the ion-signal detection/control circuit 300.
As a result, the current mirror circuit 305 in the ion-signal detection/control circuit 300 is activated, and the collector current, corresponding to the ion current that flows through the PNP transistor 304, flows through the PNP transistor 303 in the current mirror circuit 305. The outputted current is converted into a voltage by the ion-current detection resistor 306 and transferred, as an analogue signal, to the ion-signal control circuit 309.
In addition, in the foregoing internal combustion engine ignition device according to Embodiment 1, by replacing the ion-signal detection/control circuit 300 by an ion-signal detection/control circuit (digital-type) 300′ illustrated in
The digital-type ion-signal detection/control circuit 300′ will be explained.
In
In the internal combustion engine ignition device, according to Embodiment 1 of the present invention, configured as described above, even in the case where, as represented by a timing chart in
Moreover, even in the case where, as represented by a timing chart in
An internal combustion engine ignition device according to Embodiment 2 of the present invention is configured in such a way that, in the foregoing Embodiment 1, as an example represented in
According to Embodiment 2, the pulse detection circuit 7 can readily distinguish between the energization start signal Igt1′ and the de-energization signal Igt2′ that are outputted from the pulse generation circuit 201.
An internal combustion engine ignition device according to Embodiment 3 of the present invention is configured in such a way that, in the foregoing Embodiment 1, the value of the input impedance 6 in the coil driver 400 is set to be extremely large compared with the value of the resistor 204 in the ECU 200.
According to Embodiment 3, even in the case where, while the pulse generation circuit generates the energization start signal Igt1 or the de-energization signal Igt2, an ion current flows, no electric current flows in the ion-current-output current mirror circuit 10; therefore, the pulse generation circuit 201 can stably supply the energization start signal Igt1 and the de-energization signal Igt2, and the ion detection can stably be performed without affecting the ignition signal.
An internal combustion engine ignition device according to Embodiment 4 of the present invention is configured in such a way that, in the foregoing Embodiment 1, as an example represented in
According to Embodiment 4, even in the case where noise such as a surge voltage intrudes in the input signal line of the coil driver 400, the noise is not recognized as the energization start signal or the de-energization signal because high-frequency noise and low-frequency noise each include continuous noise signals that are of the same frequency; therefore, problems such as re-energization of the primary coil and erroneous ignition can be avoided.
An internal combustion engine ignition device according to Embodiment 5 is configured in such a way that, in the foregoing Embodiment 1, provision is made, in the coil driver 400, for a response circuit that transmits a signal that indicates the start of energization, in a constant time after detecting the fact that the pulse generation circuit 201 has supplied the energization start signal Igt1 to the pulse detection circuit 7, and provision is made, in the ECU 200, for a response monitoring circuit that detects the signal transmitted by the response circuit.
According to Embodiment 5, during the time period between the time points t1 and t2 in the timing chart in
An internal combustion engine ignition device according to Embodiment 6 of the present invention is configured in such a way that, in the foregoing Embodiment 5, provision is made, in the ECU 200, for a function for recurrently transmitting the same signal in the case where the operation status detected by the response monitoring circuit is different from a predetermined operation status.
According to Embodiment 6, even in the case where, during the time period between the time points t1 and t2 in the timing chart represented in
As illustrated in
At the timing when the pulse generation circuit 501 outputs neither the energization start signal Igt1 nor the de-energization signal Igt2, the input voltage Igt of the coil 700 including a coil driver is set to a high level (from 5 V to 14 V), and at the timing when the pulse generation circuit 501 outputs the energization start signal Igt1 or the de-energization signal Igt2, the input voltage Igt of the coil 700 including a coil driver is lowered for an extremely short time from the high level (from 5 V to 14 V) to a low level (0 V), so that the coil 700 including a coil driver recognizes the change in the input voltage Igt as the energization start signal Igt1 or the de-energization signal Igt2 and flows and interrupts the primary-coil current I1 so as to generate a high voltage for igniting the ignition plug 14.
The coil 700 including a coil driver detects a signal outputted through a series of operations thereof and extracts a constant current I3 from the ECU 500.
In addition, the input voltage Igt of the coil 700 including a coil driver at this timing is given by the following equation:
Igt≈the voltage of the internal power source of the ECU 500−(the constant current I3×the resistance value of a resistor 503)
As a result, a coil-output-signal detection/control circuit 600 is activated, and a coil output signal is transferred to the coil-output-signal detection/control circuit 600.
By performing an analysis based on the coil output signal, a malfunction of the coil 700 including a coil driver is detected.
Next, the internal combustion engine ignition device according to Embodiment 7, in the case where the primary-coil current I1 is utilized as the signal that is detected by the coil 700 including a coil driver, will be described specifically, with reference to
The pulse detection circuit 17 is a circuit in which the energization start signal Igt1 and the de-energization signal Igt2 are stored; the pulse detection circuit 17 recognizes the signal received from the pulse generation circuit 501 as the energization start signal Igt1 or the de-energization signal Igt2 and supplies an ignition signal to the switching element 15 in the later stage, thereby driving the switching element 15. The switching element 15 is, for example, an IGBT (insulated gate bipolar transistor (IGBT); the gate terminal is connected to the pulse detection circuit 17, the collector terminal is connected to the primary coil 12 of the ignition coil 11, and the emitter terminal is connected to a detection resistor 18 and the coil-output-signal detection circuit 19. The other terminal of the detection resistor 18 is connected to the reference potential point GND.
The coil-output-signal detection circuit 19 is configured in such a way as to have an output terminal 19a and an input terminal 19b. The output terminal 19a is connected to an input impedance 16 and the pulse detection circuit 17, and the input terminal 19b is connected to the emitter terminal of the switching element 15 and the detection resistor 18. The coil-output-signal detection circuit 19 is configured with a current mirror circuit 192 including N-channel MOSFETs 190 and 191, an internal power source 193, a current source 194, a P-channel MOSFET 195, an AND circuit 196, and a window comparator circuit 199 including comparator circuits 197 and 198.
The gate of the N-channel MOSFET 190 is connected to the gate of the N-channel MOSFET 191; the drain is connected to the output terminal 19a; the source is connected to the ground GND. The gate of the N-channel MOSFET 191 is connected to the drain of the N-channel MOSFET 191, the current source 194, and the source of the P-channel MOSFET 195. The other terminal of the current source 194 is connected to the internal power source 193. The internal power source 193 is a stabilized power source. The gate of the P-channel MOSFET 195 is connected to the output terminal of the AND circuit 196, and the drain is connected to the ground GND. One input terminal of the AND circuit 196 is connected to the output terminal of the comparator circuit 197; the other input terminal is connected to the output terminal of the comparator circuit 198. The input terminal (+) of the comparator circuit 197 is connected to the input terminal 19b; the input terminal (−) is connected to a reference voltage (Vth1). The input terminal (+) of the comparator circuit 198 is connected to a reference voltage (Vth2); the input terminal (−) is connected to the input terminal 19b.
Next, the inner configuration of the coil-output-signal detection/control circuit 600 will be explained. The coil-output-signal detection/control circuit 600 is provided with an internal power source 601, the P-channel MOSFET 602, a current mirror circuit 605 including PNP transistors 603 and 604, a coil-output-signal detection resistor 606, and a coil-output-signal control circuit 609.
The gate of the P-channel MOSFET 602 is connected to the pulse generation circuit 501; the drain is connected to the emitters of the PNP transistors 603 and 604; the source is connected to the internal power source 601. The internal power source 601 is a stabilized power source. The base of the PNP transistor 603 is connected to the base of the PNP transistor 604, and the collector of the PNP transistor 603 is connected to the coil-output-signal detection resistor 606 and the coil-output-signal control circuit 609. The base of the PNP transistor 604 is connected to the collector of the PNP transistor 604 and a resistor 503. The other terminal of the coil-output-signal detection resistor 606 is connected to the ground GND.
After that, at the time point t3 when a voltage Vdet, which is produced when the primary-coil current I1 flows through the detection resistor 18, is between Vth1 and Vth2, the output of the window comparator circuit 199 becomes high-level, whereby the P-channel MOSFET 195 turns off. The constant current I3 is supplied from the current source 194 to the current mirror circuit 192 at this time instant, and then the current mirror circuit 192 is activated. The N-channel MOSFET 190 in the current mirror circuit 192 extracts a drain current, corresponding to the constant current I3 that flows through the N-channel MOSFET 191, from the current mirror circuit 605 in the coil-output-signal detection/control circuit 600.
As a result, the current mirror circuit 605 in the coil-output-signal detection/control circuit 600 is activated, and the collector current, corresponding to the constant current I3 that flows through the PNP transistor 604, flows through the PNP transistor 603 in the current mirror circuit 605. The outputted current is converted into a voltage by the coil-output-signal detection resistor 606 and transferred to the coil-output-signal control circuit 609.
After that, at the time point t4 when the voltage Vdet is larger than Vth2, the output of the window comparator circuit 199 becomes low-level, whereby the P-channel MOSFET 195 turns on. The gate voltages of the N-channel MOSFETs 190 and 191 become low-level at this time instant, and then the operation of the current mirror circuit 192 stops. On that occasion, the current supply to the coil-output-signal detection resistor 606 stops.
As described above, in the internal combustion engine ignition device according to Embodiment 7, in the case where some sort of failure such as breakage of the primary coil 12 is caused in the coil 700 including a coil driver, the ECU 500 can detect the abnormality and can perform a failure diagnosis.
Moreover, by, as the coil output signal to be detected, utilizing a primary-coil voltage, a secondary-coil current, a secondary-coil voltage, or the like, the failure diagnosis on the coil 700 including a coil driver can widely be performed.
In addition, the foregoing Embodiments 2 to 6 are applicable not only to Embodiment 1 but also to Embodiment 7.
Various modifications and alterations of this invention will be apparent to those skilled in the art without departing from the scope and spirit of this invention, and it should be understood that this is not limited to the illustrative embodiments set forth herein.
Number | Date | Country | Kind |
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2008-11684 | Jan 2008 | JP | national |