JP2015200249A - Igniter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an igniter 1 for an internal combustion engine including an energy input circuit 9, capable of suppressing a control failure that may occur due to the superimposition of electromagnetic noise generated in a primary line on a secondary line.SOLUTION: An igniter 1 comprises assemblies 31 each including an ignition coil 3, a main ignition circuit 8, a feedback circuit 10, and input energy control means 16 as many as cylinders of an engine. With this configuration, a primary line for supplying a primary current to a primary coil of the ignition coil 3 and a secondary line for feeding back a secondary current to the energy input circuit 9 can be included in each assembly 31. Owing to this, it is possible to suppress the emission of electromagnetic noise by the primary line and the superimposition of the electromagnetic noise on the secondary line. As a result, it is possible to suppress a control failure that occurs due to the superimposition of the electromagnetic noise generated in the primary line on the secondary line in the igniter 1 including energy input circuit 9.

Description

  The present invention relates to an ignition device used for an internal combustion engine (engine).

The following energy input circuit has been devised as a technique for reducing the burden on the spark plug, suppressing unnecessary power consumption, and continuing the spark discharge (for details, see Japanese Patent Application No. 2013-082958. This technique is not known). ). The energy input circuit supplies electric energy from the negative side of the primary coil before the spark discharge (hereinafter referred to as main ignition) started by a so-called full-trait ignition circuit disappears, and the secondary in the same direction as the main ignition. By causing the current to flow continuously, the spark discharge generated as the main ignition is continued for an arbitrary period.
Hereinafter, the spark discharge that is continued by the energy input circuit, that is, the spark discharge following the main ignition is referred to as a continuous spark discharge. Further, a period in which the continuous spark discharge continues is called a discharge continuation period.

The energy input circuit controls the primary current during the discharge duration to adjust the secondary current and maintain the spark discharge. In addition, by adjusting the secondary current during the continuous spark discharge, it is possible to reduce the burden on the spark plug, suppress unnecessary power consumption, and continue the spark discharge.
Furthermore, in order to keep the spark discharge stable without being affected by individual device differences, aging deterioration, and the variety of discharge environments, a configuration was added to add a feedback circuit that detects the secondary current and feeds it back to the energy input circuit. (See Japanese Patent Application No. 2013-246091. This technique is not publicly known.)

Next, for the purpose of assisting understanding of the present invention, a representative example of an energy input circuit to which the present invention is not applied will be described with reference to FIG.
The ignition device 100 shown in FIG. 8 includes a main ignition circuit 102 that causes the ignition plug 101 to generate main ignition based on a full tiger, and an energy input circuit 103 that continues the main ignition to generate continuous spark discharge.

  When the switching element 104 is turned on, the main ignition circuit 102 causes a positive primary current to flow from the in-vehicle battery 105 to the primary coil 106 to store magnetic energy, and when the switching element 104 is turned off, the magnetic energy is generated by electromagnetic induction. Is converted into electric energy to generate a high voltage in the secondary coil 107 to cause main ignition. The energy input circuit 103 boosts the voltage of the in-vehicle battery 105 in the booster circuit 108 and stores the boosted voltage in the capacitor 109, and the electrical energy stored in the capacitor 109 is transferred to the negative side of the primary coil 106 by turning on and off the switching element 110. throw into.

  8 includes a feedback circuit 111 that detects a secondary current and feeds it back to the energy input circuit 103. The feedback circuit 111 supplies the detected secondary current to the driver circuit of the energy input circuit 103. give feedback.

(problem)
By the way, the following aspect was proposed as a component structure of an ignition device provided with an energy input circuit. That is, in this aspect, the same number of coil housings as the number of cylinders are provided, and one controller housing is provided that includes the same number of main ignition circuits and energy input circuits as the number of cylinders.

  However, in such a component aspect, a wiring (primary side wiring) for energizing the primary coil in the main ignition circuit or the energy input circuit, or a wiring for feeding back the secondary current to the energy input circuit in the feedback circuit. (Secondary side wiring) is arranged outside the casing. For this reason, electromagnetic noise radiated from the primary side wiring may be superimposed on the secondary side wiring to adversely affect the control of the energy input circuit based on the secondary current, and control failure may occur.

(Reference technology)
Patent Document 1 discloses a technique for detecting a primary current and a secondary current and using them for controlling multiple discharges in an ignition device that does not include an energy input circuit and performs so-called multiple discharge. However, even in the technique of Patent Document 1, it is normal that the ignition coil and the various circuits are configured separately, and the ignition coil and the various circuits are connected by wiring outside the housing. It is done.

JP 2009-228507 A

  The present invention has been made in view of the above problems, and an object thereof is to superimpose electromagnetic noise generated in the primary wiring on the secondary wiring in an ignition device for an internal combustion engine having an energy input circuit. It is in suppressing the control failure which arises by this.

The ignition device for an internal combustion engine of the first invention of the present application includes the following main ignition circuit, energy input circuit, and feedback circuit.
The main ignition circuit performs energization control of the primary coil of the ignition coil to cause spark discharge in the spark plug. The energy input circuit performs energization control of the primary coil during the spark discharge started by the operation of the main ignition circuit, and continuously supplies a secondary current in the same direction to the secondary coil of the ignition coil. The spark discharge started by the operation of the ignition circuit is continued. Further, the feedback circuit detects the secondary current and feeds it back to the energy input circuit.

The energy input circuit includes a booster circuit that boosts the voltage of the on-vehicle battery and stores it as electric energy, and an input energy control unit that controls the input of the electric energy stored in the booster circuit to the negative side of the primary coil. Have.
The ignition coil, the main ignition circuit, the feedback circuit, and the input energy control means are provided in the same number as the number of cylinders of the internal combustion engine as one assembly, and are assembled to each cylinder.

  As a result, wiring for supplying the primary current to the primary coil (primary side wiring) and wiring for feeding back the secondary current to the energy input circuit (secondary side wiring) are incorporated in the coil casing. And can be shortened. For this reason, the radiation of the electromagnetic noise by the primary side wiring and the superimposition of the electromagnetic noise on the secondary side wiring can be suppressed. As a result, in an ignition device for an internal combustion engine provided with an energy input circuit, it is possible to suppress a control failure caused by superimposing electromagnetic noise generated in the primary side wiring on the secondary side wiring.

According to the second invention subordinate to the first invention of the present application, the total number of booster circuits is less than the number of cylinders, and in the booster circuit, the primary coils of other cylinders are electrically connected to the primary coils of the other cylinders. There is something that inputs energy.
As a result, the total number of booster circuits can be reduced to reduce the cost.

According to the third invention subordinate to the first and second inventions of the present application, the assembly includes a protection circuit that protects the main ignition circuit and the energy input circuit from overcurrent and overvoltage, and the protection circuit is included in one assembly. Shared by main ignition circuit and energy input circuit.
Thereby, the cost regarding a protection circuit can be reduced.

According to the fourth invention subordinate to the first to third inventions of the present application, the booster circuit stores electrical energy for driving devices other than the ignition device.
According to the fifth invention of the present application, the energy input circuit is supplied with power from a high voltage battery having a voltage higher than that of the battery supplying power to the main ignition circuit, and the input energy control means converts the electric energy of the high voltage battery to the minus value of the primary coil. Control to throw to the side.
As a result, the cost associated with the booster circuit can be reduced.

1 is a configuration diagram of an ignition device (Example 1). FIG. 2 is a time chart showing the operation of the ignition device (Example 1). (Example 1) which is a block diagram which shows the arrangement | positioning aspect of the assembly of an ignition device. (Example 2) which is a block diagram which shows the arrangement | positioning aspect of the assembly of an ignition device. (Example 3) which is a block diagram which shows the arrangement | positioning aspect of the assembly of an ignition device. (Example 4) which is a block diagram which shows the arrangement | positioning aspect of the assembly of an ignition device. (Example 5) which is a block diagram which shows the arrangement | positioning aspect of the assembly of an ignition device. It is a block diagram of an ignition device (reference example).

  Hereinafter, modes for carrying out the invention will be described using examples. In addition, an Example discloses a specific example, and it cannot be overemphasized that this invention is not limited to an Example.

[Configuration of Example 1]
The ignition device 1 according to the first embodiment will be described with reference to FIG.
The ignition device 1 is mounted on a spark ignition engine for running a vehicle, and ignites an air-fuel mixture in a combustion chamber at a predetermined ignition timing. An example of the engine is a direct injection engine capable of lean burn using gasoline as fuel, and a swirl flow control means for generating a swirl flow of an air-fuel mixture such as a tumble flow or a swirl flow in a cylinder. Prepare. In an operating state where the gas flow rate in the cylinder is high and there is a possibility that the spark discharge is blown out, such as lean burn, the ignition device 1 is controlled to perform continuous spark discharge following the main ignition.

The ignition device 1 is a DI (direct ignition) type that uses an ignition coil 3 corresponding to each ignition plug 2 of each cylinder.
Further, the ignition device 1 controls the primary coil 5 of the ignition coil 3 based on signals such as an ignition signal IGt and a discharge continuation signal IGw given from an electronic control unit (hereinafter referred to as ECU 4) that forms the center of engine control. The energization control is performed, and the electric energy generated in the secondary coil 6 of the ignition coil 3 is controlled by energizing the primary coil 5 to control the spark discharge of the spark plug 2.

  Here, the ECU 4 is mounted on the vehicle from various sensors that detect the operating state and control state of the engine (warm-up state, engine rotational speed, engine load, presence / absence of lean combustion, degree of swirling flow, etc.). A signal is input. The ECU 4 also includes an input circuit that processes an input signal, a CPU that performs control processing and arithmetic processing related to engine control based on the input signal, and various types of data stored and held such as data and programs necessary for engine control. And an output circuit for outputting signals necessary for engine control based on the processing results of the memory and CPU. Then, the ECU 4 generates and outputs an ignition signal IGt and a discharge continuation signal IGw corresponding to engine parameters acquired from various sensors.

  The ignition device 1 according to the first embodiment includes a main ignition circuit 8 that generates main ignition based on a full tiger, an energy input circuit 9 that continues a spark discharge generated as main ignition as a continuous spark discharge by adding additional electric energy, and 2 And a feedback circuit 10 that detects the next current and feeds it back to the energy input circuit 9.

The spark plug 2 has a well-known structure, and includes a center electrode connected to one end of the secondary coil 6 and a ground electrode grounded through an engine cylinder head or the like. The generated electrical energy causes a spark discharge between the center electrode and the ground electrode.
The ignition coil 3 includes a primary coil 5 and a secondary coil 6, and a current (secondary current) is supplied to the secondary coil 6 by electromagnetic induction in accordance with increase / decrease of a current (primary current) flowing through the primary coil 5. It is a well-known structure that generates

  One end of the primary coil 5 is connected to the plus electrode of the on-vehicle battery 12, and the other end of the primary coil 5 is grounded via the ignition switching means 13 of the main ignition circuit 8. Further, an energy input circuit 9 is connected to the other end of the primary coil 5 in parallel with a line grounded via the ignition switching means 13.

  One end of the secondary coil 6 is connected to the center electrode of the spark plug 2 as described above, and the other end of the secondary coil 6 is connected to the feedback circuit 10. The other end of the secondary coil 6 is connected to the feedback circuit 10 via a first diode 14 that limits the direction of the secondary current to one direction.

  The main ignition circuit 8 causes the primary coil 5 to store energy when the ignition switching means 13 is turned on and off, and also uses the energy stored in the primary coil 5 to generate a high voltage in the secondary coil 6 for ignition. Main ignition is caused to the plug 2.

  More specifically, the main ignition circuit 8 includes an ignition switching means 13 and an ignition driver circuit 13a for intermittently energizing the primary coil 5. Here, the ignition driver circuit 13a gives a control signal to the ignition switching means 13 to turn on and off the ignition switching means 13, and turns on the ignition switching means 13 during a period when the ignition signal IGt is given from the ECU 4. It is provided to do.

  The main ignition circuit 8 turns on the ignition switching means 13 during a period in which the ignition signal IGt is given from the ECU 4, thereby applying a positive primary current by applying the voltage of the on-vehicle battery 12 to the primary coil 5. The magnetic energy is stored in the primary coil 5. Thereafter, when the ignition switching means 13 is turned off, the main ignition circuit 8 converts magnetic energy into electric energy by electromagnetic induction and generates a high voltage in the secondary coil 6 to cause main ignition.

  The ignition switching means 13 is a power transistor, a MOS transistor, a thyristor, or the like. Further, the ignition signal IGt is a signal for instructing a period during which the primary coil 5 stores magnetic energy in the main ignition circuit 8 and an ignition start timing.

The energy input circuit 9 includes the following booster circuit 15 and input energy control means 16.
First, the booster circuit 15 boosts the voltage of the in-vehicle battery 12 and stores it in the capacitor 18 during a period when the ignition signal IGt is given from the ECU 4.
Next, the input energy control means 16 inputs the electric energy stored in the capacitor 18 to the negative side (ground side) of the primary coil 5.

In addition to the capacitor 18, the booster circuit 15 includes a choke coil 19, a boosting switching unit 20, a booster driver circuit 21, and a second diode 22. Note that the boosting switching means 20 is, for example, a MOS transistor.
Here, one end of the choke coil 19 is connected to the plus electrode of the in-vehicle battery 12, and the energization state of the choke coil 19 is interrupted by the boosting switching means 20. Further, the boosting driver circuit 21 supplies a control signal to the boosting switching means 20 to turn on and off the boosting switching means 20, and the magnetic energy stored in the choke coil 19 by the on / off operation of the boosting switching means 20. Is charged as electrical energy by the capacitor 18.

Note that the boosting driver circuit 21 is provided so as to repeatedly turn on and off the boosting switching means 20 at a predetermined period during a period when the ignition signal IGt is given from the ECU 4.
The second diode 22 prevents the electrical energy stored in the capacitor 18 from flowing back to the choke coil 19 side.

The input energy control means 16 includes the following input switching means 24, input driver circuit 25, and third diode 26. The switching means 24 for making up is, for example, a MOS transistor.
Here, the input switching means 24 turns on / off the electric energy stored in the capacitor 18 from being input to the primary coil 5 from the minus side, and the input driver circuit 25 gives a control signal to the input switching means 24. To turn it on and off.

Then, the making driver circuit 25 controls the electric energy to be inputted from the capacitor 18 to the primary coil 5 by turning on and off the making switching means 24 so that the secondary current is predetermined during the period in which the discharge continuation signal IGw is given. Keep it at the value. Here, the discharge continuation signal IGw is a signal for instructing a period during which the continuous spark discharge is continued. More specifically, the on / off switching means 24 is repeatedly turned on and off to cause the primary coil 5 to be electrically connected to the booster circuit 15. This is a signal for instructing a period during which energy is input.
The third diode 26 prevents the backflow of current from the primary coil 5 to the capacitor 18.

The feedback circuit 10 detects the secondary current and feeds it back to the input energy control means 16 of the energy input circuit 9.
Here, the feedback circuit 10 is provided with a secondary current detection resistor 28 for detecting a secondary current and a current detection circuit 29 for synthesizing and outputting a feedback signal. The detected value of the secondary current is converted into a voltage by the secondary current detection resistor 28 and output to the current detection circuit 29. In the current detection circuit 29, for example, upper and lower thresholds for the secondary current are set, and a feedback signal corresponding to the comparison between the detected value and the upper and lower thresholds is synthesized to the input driver circuit 25. Is output.

Next, the normal operation of the ignition device 1 will be described with reference to FIG.
In FIG. 2, “IGt” represents the input state of the ignition signal IGt as high / low, and “IGw” represents the input state of the discharge continuation signal IGw as high / low. Further, “I1” and “V1” respectively represent a primary current (a current value flowing through the primary coil 5) and a primary voltage (a voltage value applied to the primary coil 5), and “I2” and “V2”. Represents a secondary current (a current value flowing through the secondary coil 6) and a secondary voltage (a voltage value applied to the secondary coil 6). Furthermore, “Vdc” represents the electrical energy stored in the capacitor 18 as a voltage value.

  When the ignition signal IGt switches from low to high (see time t01), during the period when the ignition signal IGt is high, the ignition switching means 13 is maintained in an on state and a positive primary current flows, and the primary coil 5 Magnetic energy is stored in Further, the boosting switching means 20 repeatedly turns on and off to perform a boosting operation, and the boosted electrical energy is stored in the capacitor 18.

Eventually, when the ignition signal IGt switches from high to low (see time t02), the ignition switching means 13 is turned off, and the energized state of the primary coil 5 is suddenly cut off. Thereby, the magnetic energy stored in the primary coil 5 is converted into electric energy, a high voltage is generated in the secondary coil 6, and main ignition is started in the spark plug 2.
After the main ignition is started in the spark plug 2, the secondary current attenuates in a substantially triangular wave shape (see the dotted line I2). Then, the discharge continuation signal IGw switches from low to high before the secondary current reaches the lower limit threshold (see time t03).

  When the discharge continuation signal IGw switches from low to high, the on / off switching means 24 is on / off controlled, and the electric energy stored in the capacitor 18 is sequentially input to the negative side of the primary coil 5 and the primary current is It flows from the primary coil 5 toward the plus electrode of the in-vehicle battery 12. More specifically, a primary current from the primary coil 5 toward the positive electrode of the in-vehicle battery 12 is added each time the input switching unit 24 is turned on, and the primary current increases to the negative side (time). (See t03 to t04.)

Each time the primary current is added, a secondary current in the same direction as the secondary current caused by the main ignition is sequentially added to the secondary coil 6, and the secondary current is maintained between the upper and lower limits.
As described above, by controlling the on / off switching means 24, the secondary current continuously flows to such an extent that the spark discharge can be maintained. As a result, if the ON state of the discharge continuation signal IGw continues, continuous spark discharge is maintained in the spark plug 2.

Next, a characteristic configuration of the first embodiment will be described with reference to FIGS. 1 and 3.
First, according to the ignition device 1 of the first embodiment, the ignition coil 3, the main ignition circuit 8, the feedback circuit 10, and the input energy control means 16 are housed and arranged in one case as one unit to form an assembly 31. The number of the assemblies 31 is the same as the number of cylinders of the engine, and is assembled to each cylinder. Each assembly 31 is provided with the following protection circuit 32 and noise reduction circuit 33 (in the following description, the number of engine cylinders is four, and four assemblies 31 are provided). And).

  The protection circuit 32 protects the ignition driver circuit 13a and the input driver circuit 25 from overcurrent and overvoltage, and the noise reduction circuit 33 outputs the electric power supplied from the in-vehicle battery 12 and the ignition signal IGt output from the ECU 4. And the noise of the discharge continuation signal IGw is removed. The protection circuit 32 is shared by the main ignition circuit 8 and the energy input circuit 9 in one assembly 31.

  Further, the assembly 31 of the first embodiment is provided with one booster circuit 15 for all four. Further, all the booster circuits 15 are supplied with electric power from the in-vehicle battery 12, and in each assembly 31, the boosted electrical energy is supplied from the booster circuit 15 to the input energy control means 16.

The booster circuit 15 according to the first embodiment cannot supply electric energy to the input energy control unit 16 of the different assembly 31. That is, the booster circuit 15 provided in the # 1 cylinder assembly 31 cannot supply electric energy to the input energy control means 16 provided in the # 2 to # 4 cylinder assembly 31. The same applies to the booster circuit 15 provided in the four-cylinder assembly 31.
In the following description, the assembly 31 that can supply electric energy only between the booster circuit 15 and the input energy control means 16 of the same cylinder may be referred to as an independent type 31A.

[Effect of Example 1]
According to the ignition device 1 of the first embodiment, the ignition coil 3, the main ignition circuit 8, the feedback circuit 10, and the input energy control means 16 are provided as one assembly 31, which is the same number as the number of cylinders of the engine. It is assembled to the cylinder.
As a result, wiring (primary side wiring) for energizing the primary current to the primary coil 5 and wiring (secondary side wiring) for feeding back the secondary current to the energy input circuit 9 are supplied to the assembly 31. Can be built in.

  For this reason, the radiation of the electromagnetic noise by the primary side wiring and the superimposition of the electromagnetic noise on the secondary side wiring can be suppressed. As a result, in the ignition device 1 including the energy input circuit 9, it is possible to suppress control failure caused by superimposing electromagnetic noise generated in the primary side wiring on the secondary side wiring.

The assembly 31 includes a protection circuit 32 that protects the ignition driver circuit 13a and the input driver circuit 25 from overcurrent and overvoltage. The protection circuit 32 includes the main ignition circuit 8 and the energy input circuit in one assembly 31. 9 shared.
Thereby, the cost concerning the protection circuit 32 can be reduced.

Furthermore, according to the ignition device 1 of the first embodiment, the assemblies 31 are all independent types 31A.
Thus, even if the booster circuit 15 fails in any of the cylinders, the electric energy boosted by the booster circuit 15 can be input to the primary coil 5 in the cylinders in which the booster circuit 15 has not failed. For this reason, continuous spark discharge can be continued in the cylinder in which the booster circuit 15 has not failed.

[Configuration of Example 2]
According to the ignition device 1 of the second embodiment, as shown in FIG. 4, only the assembly 31 corresponding to the # 1 cylinder has the booster circuit 15, and the assembly 31 corresponding to the # 2 to # 4 cylinders is the booster circuit 15.
Does not have. That is, in the ignition device 1 according to the second embodiment, the total number of booster circuits 15 is 1, which is smaller than the number of cylinders 4. Electric energy is supplied from the booster circuit 15 of the # 1 cylinder to the input energy control means 16 of the # 2 to # 4 cylinders. Therefore, the primary coil 5 of the # 2 to # 4 cylinders is supplied with the electric energy boosted by the booster circuit 15 of the # 1 cylinder, and the continuous spark discharge in the # 2 to # 4 cylinders is It continues by the electric energy boosted by the booster circuit 15.

  In the following description, the assembly 31 that can supply electric energy from the booster circuit 15 of its own cylinder not only to the input energy control means 16 of its own cylinder but also to the input energy control means 16 of other cylinders is referred to as a supply type 31B. Sometimes. Further, the assembly 31 that does not have the booster circuit 15 and receives electric energy from another power source in the input energy control means 16 of the own cylinder may be referred to as a receiving type 31C.

[Effect of Example 2]
According to the ignition device 1 of the second embodiment, the total number of booster circuits 15 is 1, which is less than the number of cylinders 4. Only the # 1 cylinder assembly 31 is the supply type 31B, and the # 2 to # 4 cylinder assembly. 31 is a receiving type 31C.
Thereby, the total number of booster circuits 15 can be reduced and the cost can be reduced.

Example 3
According to the ignition device 1 of the third embodiment, as shown in FIG. 5, the assembly 31 of the # 1, # 2 cylinders is the supply type 31B, and the assembly 31 of the # 3, # 4 cylinders is the receiving type 31C. The total number of booster circuits 15 is 2, which is less than the number of cylinders 4. The # 3 cylinder input energy control means 16 is supplied with electric energy from the # 2 cylinder booster circuit 15, and the # 4 cylinder input energy control means 16 is supplied with electric energy from the # 1 cylinder booster circuit 15. Is supplied.

Therefore, the electric energy boosted by the booster circuit 15 of the # 2 cylinder is input to the primary coil 5 of the # 3 cylinder, and the continuous spark discharge in the # 3 cylinder is boosted by the booster circuit 15 of the # 2 cylinder. Continue with electrical energy. Also, the electric energy boosted by the booster circuit 15 of the # 1 cylinder is input to the primary coil 5 of the # 4 cylinder, and the continuous spark discharge in the # 4 cylinder is boosted by the booster circuit 15 of the # 1 cylinder. Continue with electrical energy.
As described above, also in the third embodiment, the cost can be reduced by reducing the total number of booster circuits 15.

Example 4
According to the ignition device 1 of the fourth embodiment, as shown in FIG. 6, the booster circuit 15 gives electric energy to devices other than the ignition device 1. For example, fuel is injected and supplied to the internal combustion engine. Electric energy is given to the injector 34 to be operated. That is, the booster circuit 15 according to the fourth embodiment is provided in an EDU (Electric Drive Unit) 35 that separates the function of operating a device such as the injector 34 by applying a high voltage from the ECU 4, for example, This is a DC-DC converter that boosts the voltage of the in-vehicle battery 12 to generate a high voltage.

The high voltage generated in the booster circuit 15 is given to the injector 34 via the injector drive circuit 36 to open the injector 34 and also to the input energy control means 16 of the ignition device 1.
Further, according to the ignition device 1 of the fourth embodiment, the assemblies 31 are all receiving type 31C, and electric energy is input from the EDU 35 to the primary coils 5 of all the cylinders, and the continuous spark discharge in all the cylinders is applied from the EDU 35. Continue with the electrical energy given.
As described above, in the fourth embodiment, the cost related to the booster circuit 15 can be further reduced.

Example 5
As shown in FIG. 7, the ignition device 1 according to the fifth embodiment supplies power to the energy input circuit 9 from a high voltage battery 38 having a higher voltage than the in-vehicle battery 12. For example, both the engine and the traveling motor are used. It is applied to a so-called hybrid vehicle that uses a power source. And the ignition device 1 of Example 5 employ | adopts the battery which stores the electrical energy for driving a motor for driving | running | working as the high voltage battery 38. FIG.

Further, according to the ignition device 1 of the fifth embodiment, the assemblies 31 are all receiving type 31C, and high-voltage electric energy is directly supplied from the high voltage battery 38 to the input energy control means 16 of all cylinders. . The continuous spark discharge in all cylinders is continued by the electric energy given from the high voltage battery 38.
As described above, also in the fifth embodiment, the cost related to the booster circuit 15 can be further reduced.

[Modification]
The mode of the ignition device 1 is not limited to the embodiment, and various modifications can be considered.
For example, any of the independent type 31A, the supply type 31B, and the receiving type 31C may be adopted for each of the assemblies 31 corresponding to the number of cylinders. Of the assembly 31 for the other three cylinders, one cylinder is used as the supply type 31B, and the other two cylinders are used as the reception type 31C. Energy may be supplied. Furthermore, electric energy may be supplied from the EDU 35 or the high voltage battery 38 to the input energy control means of the receiving type 31C for one cylinder of the receiving type 31C for two cylinders.

In the fourth embodiment, the DC-DC converter that applies a high voltage to a device such as the injector 34 is used as the booster circuit 15. However, the DC-DC converter that applies a high voltage to a device other than the injector 34 or the like is used as a booster circuit. You may employ | adopt as 15.
Furthermore, in the fifth embodiment, a battery that stores electrical energy for driving the traveling motor is used as the high-voltage battery 38. However, a battery that supplies electrical energy to devices other than the traveling motor is used as the high-voltage battery 38. May be.

  In the above embodiment, an example in which the ignition device 1 of the present invention is used in a gasoline engine has been shown. However, since continuous ignition can improve the ignitability of the mixture, ethanol fuel or mixed fuel is used. It may be applied to the engine. Further, even if it is used for an engine in which poor fuel may be used, the ignitability can be improved by continuous spark discharge.

  In the above-described embodiment, an example in which the ignition device 1 of the present invention is used for an engine capable of lean burn operation has been shown. However, even in a combustion state different from lean combustion, ignitability is caused by continuous spark discharge. Since improvement can be achieved, the present invention is not limited to application to an engine capable of lean combustion, and may be used for an engine that does not perform lean combustion.

  In the above embodiment, an example in which the ignition device 1 of the present invention is used in a direct injection engine that directly injects fuel into the combustion chamber has been described. However, port injection that injects fuel to the intake upstream side (inside the intake port) of the intake valve. It may be used for a formula engine.

  In the above-described embodiment, an example in which the ignition device 1 of the present invention is used for an engine that positively generates a swirl flow (such as a tumble flow or a swirl flow) of an air-fuel mixture in a cylinder has been disclosed. You may use for the engine which does not have a tumble flow control valve, a swirl flow control valve, etc.).

  In the above embodiment, the present invention is applied to the DI type ignition device 1, but a distributor type that distributes the secondary voltage to each spark plug 2 or a single cylinder engine that does not require the distribution of the secondary voltage ( For example, the present invention may be applied to the ignition device 1 of a motorcycle.

DESCRIPTION OF SYMBOLS 1 Ignition device 2 Spark plug 3 Ignition coil 5 Primary coil 6 Secondary coil 8 Main ignition circuit 9 Energy input circuit 10 Feedback circuit 12 Vehicle-mounted battery 15 Booster circuit 16 Energy input control means

Claims (5)

In an ignition device (1) for an internal combustion engine,
A main ignition circuit (8) for controlling the energization of the primary coil (5) of the ignition coil (3) to cause a spark discharge in the spark plug (2);
During the spark discharge started by the operation of the main ignition circuit (8), the energization control of the primary coil (5) is performed, and the secondary coil (6) of the ignition coil (3) is subjected to the secondary in the same direction. An energy input circuit (9) for continuously supplying a current and continuing the spark discharge started by the operation of the main ignition circuit (8);
A feedback circuit (10) for detecting the secondary current and feeding back to the energy input circuit (9);
The energy input circuit (9)
A booster circuit (15) for boosting the voltage of the vehicle-mounted battery (12) and storing it as electric energy;
Input energy control means (16) for controlling the electric energy stored in the booster circuit (15) to be input to the negative side of the primary coil (5);
The ignition coil (3), the main ignition circuit (8), the feedback circuit (10) and the input energy control means (16) are provided in the same number as the number of cylinders of the internal combustion engine as one assembly (31). Ignition device (1) characterized by being assembled to each cylinder. Ignition device (1) according to claim 1,
The total number of booster circuits (15) is smaller than the number of cylinders, and in the booster circuit (15), in addition to the primary coil (5) of its own cylinder, the primary coil (5) of another cylinder is also present. Ignition device (1) characterized in that there is something that inputs electric energy. The ignition device (1) according to claim 1 or 2,
The assembly (31) has a protection circuit (32) for protecting the main ignition circuit (8) and the energy input circuit (9) from overcurrent and overvoltage,
This protective circuit (32) is shared by the main ignition circuit (8) and the energy input circuit (9) in one assembly (31), and the ignition device (1). In the ignition device (1) according to any one of claims 1 to 3,
The booster circuit (15) stores an electrical energy for driving a device (34) other than the ignition device (1), and the ignition device (1). In an ignition device (1) for an internal combustion engine,
A main ignition circuit (8) that is fed from a predetermined battery (12), performs energization control of the primary coil (5) of the ignition coil (3), and causes a spark discharge in the spark plug (2);
During the spark discharge started by the operation of the main ignition circuit (8) and fed by a high voltage battery (38) having a higher voltage than the battery (12), energization control of the primary coil (5) is performed. An energy input circuit (9) for continuously supplying a secondary current in the same direction to the secondary coil (6) of the ignition coil (3) to continue the spark discharge started by the operation of the main ignition circuit (8). When,
A feedback circuit (10) for detecting the secondary current and feeding back to the energy input circuit (9);
The energy input circuit (9) has input energy control means (16) for controlling the electric energy of the high voltage battery (38) to be input to the negative side of the primary coil (5),
The ignition coil (3), the main ignition circuit (8), the feedback circuit (10) and the input energy control means (16) are provided in the same number as the number of cylinders of the internal combustion engine as one assembly (31). Ignition device (1) characterized by being assembled to each cylinder.

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