JPWO2018225169A1 - Ignition device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ignition device for a small internal combustion engine which suppresses wear of a discharge electrode and a ground electrode and does not cause discharge failure due to wear of the electrode and melting damage. An electromagnetic wave power source 2, an electromagnetic wave oscillator 3 that oscillates an electromagnetic wave, a control device 4 that controls the electromagnetic wave oscillator 3, and an input unit 52 that receives the electromagnetic wave oscillated from the electromagnetic wave oscillator 3. A boosting means 5 for boosting the input electromagnetic wave, a discharge electrode 55a and a ground electrode 51a forming a discharge gap, and a casing 51 having the ground electrode 51a formed on the tip side and containing the input section 52 and the discharge electrode 55a. The casing 51 is provided with a plurality of mounting holes 51A for accommodating the input section 52 and the discharge electrode 55a. [Selection diagram] Figure 1

Description

  The present invention relates to an ignition device, and more particularly to an ignition device used for an internal combustion engine.

  BACKGROUND ART Conventionally, as an ignition device for igniting an internal combustion engine, an ignition device using a plasma generation device that emits electromagnetic waves into a combustion chamber of the internal combustion engine to generate electromagnetic wave plasma has been proposed. For example, JP-A-2009-38025 and JP-A-2006-132518 describe an ignition device for an internal combustion engine using this type of plasma generation device.

  Japanese Unexamined Patent Application Publication No. 2009-38025 describes a plasma generation device that generates a spark discharge in a discharge gap of a spark plug and radiates a microwave toward the discharge gap to expand plasma. In this plasma generation device, the plasma generated by the spark discharge receives energy from the microwave pulse. This accelerates electrons in the plasma region, promotes ionization, and increases the volume of plasma.

  Japanese Patent Application Laid-Open No. 2006-132518 discloses an ignition device for an internal combustion engine that generates a plasma discharge by radiating an electromagnetic wave from an electromagnetic wave radiator into a combustion chamber. An ignition electrode insulated from the piston is provided on the upper surface of the piston. The ignition electrode plays a role in locally increasing the electric field strength of the electromagnetic wave in the combustion chamber in the vicinity thereof. This is an ignition device for an internal combustion engine in which a plasma discharge is generated near the ignition electrode.

  In addition, the present inventors have developed a plasma generation device that generates a spark discharge using only an electromagnetic wave (microwave) and can be used as an ignition device of an internal combustion engine. (See Reference 3)

JP 2009-38025 A JP 2006-132518 A International Publication No. 2014/115707

  An ignition device for an internal combustion engine that generates a spark discharge using only an electromagnetic wave (microwave) is configured such that the electromagnetic wave oscillated from an electromagnetic wave oscillator is resonated to raise the pressure by means of a boosting means between a discharge electrode and a ground electrode (discharge gap). To generate a discharge. The discharge gap is formed between the discharge electrode and a cylindrical ground electrode that covers the side surface of the discharge electrode. Usually, discharge occurs only at a predetermined location, so that the discharge electrode and the ground electrode are worn. Or erosion may occur, resulting in defective discharge.

  The present invention has been made in view of such a point, and an object of the present invention is to provide a small ignition device that suppresses abrasion of a discharge electrode and a ground electrode and does not cause a discharge failure due to abrasion or erosion of an electrode. Is to supply.

An electromagnetic wave oscillator that oscillates electromagnetic waves,
A control device for controlling the electromagnetic wave oscillator,
An input unit that receives supply of electromagnetic waves oscillated from the electromagnetic wave oscillator,
Step-up means for stepping up an input electromagnetic wave, a discharge electrode and a ground electrode forming a discharge gap,
A casing incorporating the input unit and the discharge electrode with the ground electrode provided on the tip side,
The casing is an ignition device having a plurality of mounting holes for accommodating the input section and the discharge electrodes.

  An igniter according to the present invention is an igniter that boosts an electromagnetic wave to increase a potential difference between a discharge electrode and a ground electrode to generate a discharge, in which a plurality of input portions and a discharge electrode are provided in a casing having the ground electrode. By switching the output of the electromagnetic wave from the electromagnetic wave oscillator to the output destination of the electromagnetic wave every cycle of the internal combustion engine using the switching means, the discharge electrode and the ground electrode used for the discharge can be cycled. Wear can be reduced by making it different every time.

  Further, the discharge electrode is formed at the tip of an electrode shaft portion extending from the bottomed cylindrical portion through which the input shaft portion extending from the input portion is inserted to the side opposite to the input portion, and the cylindrical portion has a cylindrical insulating shape. It can be arranged in the mounting hole in a state of being inserted into the body.

  Further, the boosting means includes a first resonance space formed between the cylindrical portion and a casing covering the cylindrical portion, and a second resonance space formed between the electrode shaft portion and the casing covering the electrode shaft portion. Can be configured.

  Further, in this case, the boosting means can be configured so that the resonance frequency differs for each mounting hole of the casing. Thus, the frequency of the oscillating electromagnetic wave is changed to the resonance frequency of the booster corresponding to each cycle of the internal combustion engine, so that the discharge electrode and the ground electrode used for the discharge are set to different places every cycle.

  ADVANTAGE OF THE INVENTION According to the igniter of this invention, generation | occurrence | production of a plasma, expansion and maintenance can be performed efficiently using only an electromagnetic wave, without requiring a spark plug which discharges by a high voltage, a complicated system, etc., and the igniter And an ignition device that suppresses a discharge failure caused by electrode wear or melting.

1 is a block diagram of an ignition device for an internal combustion engine according to a first embodiment. FIG. 2 shows the ignition device, in which (a) is an overall sectional view, and (b) is a partially enlarged sectional view showing a discharge gap portion. 3A and 3B show a casing of the ignition device, wherein FIG. 3A is a plan view, FIG. 3B is a sectional front view, and FIG. 3C is a sectional view of a tubular part, an electrode shaft part, and a discharge part formed integrally. It is an equivalent circuit of the booster circuit of the ignition device. It is a perspective view of the same ignition device.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that the following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

<First Embodiment> Ignition Device The first embodiment is an ignition device for an internal combustion engine according to the present invention. As shown in FIGS. 1 and 2, the ignition device 1 includes an electromagnetic wave power supply 2, an electromagnetic wave oscillator 3 for oscillating electromagnetic waves, a control device 4 for controlling the electromagnetic wave power supply 2 and the electromagnetic wave oscillator 3, and an electromagnetic wave oscillator 3. An input unit 52 that receives supply of electromagnetic waves oscillated from the input unit, a boosting unit 5 that boosts the input electromagnetic waves, a discharge electrode 55a and a ground electrode 51a that form a discharge gap, and a ground electrode 51a that is formed on the tip side. A casing 51 incorporating the input section 52 and the discharge electrode 55a is provided. The casing 51 is provided with a plurality of mounting holes 51A for accommodating the input section 52 and the discharge electrode 55a.

  The discharge electrode 55a is formed at the tip of an electrode shaft portion 55b extending from the bottomed cylindrical portion 54 through which the input shaft portion 53 extending from the input portion 52 is inserted to the side opposite to the input portion. An input shaft portion 53 extending from the input portion 52 is insulated from the tubular portion 54. Specifically, a tubular insulator 59 is interposed between the tubular portion 54 and the inner peripheral surface of the tubular portion 54. By interposing the insulator 59 or not contacting the inner peripheral surface of the cylindrical portion 54, the cylindrical portion 54 and the input shaft portion 53 are capacitively coupled to form an equivalent circuit C1 described later. The cylindrical portion 54 and the electrode shaft portion 55b are also electrically insulated from the inner peripheral surface of the casing 51. In the present embodiment, the tubular portion 54 and the electrode shaft portion 55b are included in a tubular insulator 59. An equivalent circuit C2 described later is formed between the outer peripheral surface of the cylindrical portion 54 and the inner peripheral surface of the casing 51 covering the cylindrical portion 54, and between the electrode shaft portion 55b and the inner peripheral surface of the casing 51. The capacitor C3 of the equivalent circuit is formed.

  The booster 5 is configured by an equivalent circuit shown in FIG. The booster 5 forms a resonance structure at three places between the above-described capacitors C1, C2, and C3 using the electrode shaft portion 55b as the coil L so as to boost the supplied electromagnetic wave. In particular, the first resonance region formed by the capacitor C2 formed between the outer peripheral surface of the cylindrical portion 54 and the inner peripheral surface of the casing 51 covering the cylindrical portion 54, and the casing 51 covering the electrode shaft portion 55b and the electrode shaft portion 55b. In this manner, the supplied electromagnetic wave is boosted by the second resonance region formed by the capacitor C3 formed between the discharge electrode 55a and the potential difference between the discharge electrode 55a and the ground electrode 51a to several tens of kV to cause discharge. I have. The input shaft 53 and the cylindrical portion 54 may be electrically connected to each other so as not to be capacitively coupled, so that the equivalent circuit C1 may not be formed.

  The casing 51 shown in FIG. 2 includes an input portion 52, a cylindrical portion 54, an electrode shaft portion 55b extending from the cylindrical portion 54 to the side opposite to the input portion, and a discharge electrode 55a formed at the tip of the electrode shaft portion 55b. In addition, a state in which one set of a tubular insulator 59 (hereinafter referred to as a built-in part when collectively referred to) is shown, but the ignition device 1 of the present invention is provided in a casing 51 as shown in FIG. Are formed in plural.

  The mounting hole 51A is opened in accordance with the shape of the built-in portion, and the method of fixing the built-in portion is not particularly limited, but an annular fixing member is fastened to the input portion 52 side by a fastening member (not shown). Can be fixed by

  Of the input portion 52, the tubular portion 54, and the electrode shaft portion 55b and the electrode shaft portion 55b extending from the tubular portion 54 to the non-input portion side, the tubular portion 54 shown in FIG. The resonance frequency varies depending on the external dimensions d1, the longitudinal dimension L1, the external dimensions d2 and the longitudinal dimension L2 of the electrode shaft portion, and the dimensions and dielectric constant of the insulator 59 covering these. In the ignition device according to the present embodiment, as shown in FIGS. 1 and 3A, the electromagnetic wave is branched from the electromagnetic wave transmitter 3 and supplied to each input unit 52, and each of the built-in units (shown in FIG. For example, the longitudinal length L1 of the seven cylindrical portions 54 is changed so that the resonance frequency is different. As a configuration for changing the resonance frequency, a change in the dielectric constant by changing the other dimensions or the material of the insulator 59 can be adopted.

  In the ignition device of the present invention having a plurality of built-in portions in the casing 51, the control device 4 adjusts the frequency of the electromagnetic wave oscillated from the electromagnetic wave oscillator 3 to a frequency corresponding to each built-in portion for each cycle of the internal combustion engine. (In the present embodiment, the frequency is changed to seven types according to each built-in portion), so that the discharge gap 6 between the discharge electrode 55a and the ground electrode 51a, which ignites every cycle, is controlled. Is made to fluctuate.

Even if the electromagnetic wave is supplied in parallel to the input unit 52 of each built-in unit without using a distributor as the switching means, the frequency to be changed is increased by increasing the Q value of the resonance structure of each built-in unit. , And electromagnetic waves hardly flow except at the corresponding built-in portion. Specifically, if the Q value can be set to about 120, each resonance frequency of the built-in section can be set at an interval of about 0.03 GHz before and after 2.45 GHz, and the Q value is set to about 100. In this case, it can be set at an interval of about 0.05 GHz before and after 2.45 GHz. When the Q value is set to about 120, when the electromagnetic wave of 2.45 GHz is supplied, the discharge gap 6 between the discharge electrode 55a and the ground electrode 51a of the built-in portion set to 2.42 GHz or less and 2.48 GHz or more is supplied. No discharge occurs. Q value is
Q = ω0 / (ω1−ω2).
Here, ω0: resonance frequency, ω1 and ω2 (ω1> ω2): each frequency at which the energy at the frequency ω0 is と. Therefore, the closer the values of ω1 and ω2 are to ω0, the sharper the resonance peak and the larger the Q value.

  In addition, the resonance frequency of each built-in unit may be made uniform, and the oscillation destination of the electromagnetic wave from the electromagnetic wave oscillator 3 may be switched for each cycle of the internal combustion engine using a switching unit (not shown). Absent.

  Upon receiving an electromagnetic wave oscillation signal (for example, a TTL signal) from the control device 4, the electromagnetic wave power supply 2 outputs a pulse current to the electromagnetic wave oscillator 3 in a pattern in which a predetermined duty ratio, a pulse time, and the like are set.

  The electromagnetic wave oscillator 3 is, for example, a semiconductor oscillator. The electromagnetic wave oscillator 3 is electrically connected to the electromagnetic wave power supply 2. When receiving the pulse current from the electromagnetic wave power supply 2, the electromagnetic wave oscillator 3 outputs a microwave pulse to the input unit 52. By using a semiconductor oscillator, the output, frequency, phase, duty ratio, and pulse time of an electromagnetic wave to be irradiated can be easily controlled and changed. In the present embodiment, in order to specify the igniting device 1 (built-in portion) that oscillates, as described above, the frequency of the electromagnetic wave transmitted from the electromagnetic wave oscillator 3 is set to the resonance frequency of each booster 5 for each cycle of the internal combustion engine. It is made to fluctuate according to. Further, the electromagnetic wave oscillator 3 incorporates an amplifier such as a power amplifier. This amplifier receives an ON / OFF command from the control device 4 and oscillates an electromagnetic wave from the electromagnetic wave oscillator 3 to the ignition device. The frequency fluctuation is not limited to one cycle, but may be configured to fluctuate every plural cycles.

-Operation of ignition device-
The ignition operation of the ignition device 1 will be described. In the ignition operation, the potential difference between the discharge electrode 55a and the ground electrode 51a is increased to several tens kV so that plasma is generated near the discharge gap 6.

  In a specific ignition operation, first, the control device 4 outputs an electromagnetic wave oscillation signal having a predetermined frequency fa. Upon receiving such an electromagnetic wave oscillation signal from the control device 4, the electromagnetic wave power supply 2 outputs a pulse current at a predetermined duty ratio for a predetermined set time. The electromagnetic wave oscillator 3 outputs an electromagnetic wave pulse having a frequency fa at a predetermined duty ratio over a set cycle (for example, one cycle) of the internal combustion engine. The electromagnetic wave pulse output from the electromagnetic wave oscillator 3 generates a discharge in the discharge gap 6 of the ignition device provided with the boosting means 5 having the resonance frequency fa to generate plasma.

  Subsequently, the control device 4 outputs an electromagnetic wave oscillation signal of the predetermined frequency fb. In the same procedure as above, discharge occurs in the discharge gap 6 of the ignition device provided with the booster 5 having the resonance frequency fb, and spark occurs. This operation is repeated as many times as the number of the assembled portions provided in the casing 51. Specifically, when the Q value is set to about 100, fa = 2.30 GHz and fb = 2.35 GHz so that from 2.30 GHz to 2.60 GHz from fa to fg in 0.05 GHz steps. Switch to seven different frequencies.

  The ignition device 1 shown in FIG. 5 shows an example in which three built-in portions are accommodated in a casing 51. When the discharge electrode 55a has a diameter of about 3 to 4 mm, the ignition electrode 1 of a general automobile engine ignition plug is used. It can be set to a size that can be mounted in a mounting hole of M12 mm, which is a mounting size.

-Effects of Embodiment 1-
The ignition device 1 of the first embodiment includes a plurality of discharge electrodes that can be discharged by a difference in the frequency of a supplied electromagnetic wave in a casing 51 having a ground electrode formed therein. Since a discharge can be generated at a location, it is possible to provide an ignition device that suppresses a discharge failure caused by abrasion or melting of an electrode as compared with a conventional ignition device that constantly discharges at the same position. Further, since the outer diameter of each of the mounting portions of the ignition device of the present invention can be smaller than that of a general spark plug, for example, when using a casing equivalent to an M12 size ignition plug, By incorporating the above-mentioned three built-in parts, three places of treasure halls can exhibit high ignition performance. Further, by further reducing the diameter of the discharge electrode, it is possible to accommodate 4 to 5 built-in portions and to make 4 to 5 discharge locations.

  As the internal combustion engine, a homogeneous charge compression ignition system (HCCI (Homogeneous-Charge Compression Ignition)) can be adopted. The homogeneous charge compression ignition system is a system in which gasoline is self-ignited like a diesel engine, but it is difficult to control the ignition timing because it depends on the temperature in the combustion chamber. Therefore, by using the ignition device 1 of the present invention and controlling the output of electromagnetic waves to be lower than that in the case of using a gasoline engine, it is possible to assist combustion and easily control the temperature in the combustion chamber. The disadvantage of the mixed compression ignition system can be compensated.

  As described above, since the ignition device of the present invention can generate, expand, and maintain plasma only by electromagnetic waves, only one power source is required, and a complicated transmission line or the like is not required. Therefore, the ignition device of the present invention is suitably used for internal combustion engines such as automobile engines.

DESCRIPTION OF SYMBOLS 1 Ignition device 2 Power supply for electromagnetic waves 3 Electromagnetic wave oscillator 4 Control device 5 Boosting means 6 Discharge gap 51 Casing 51a Ground electrode 52 Input part 53 Input shaft part 54 Cylindrical part 55 Center electrode 55a Discharge electrode 55b Shaft part 59 Insulator

Claims (4)

An electromagnetic wave oscillator that oscillates electromagnetic waves,
A control device for controlling the electromagnetic wave oscillator,
An input unit that receives supply of electromagnetic waves oscillated from the electromagnetic wave oscillator,
Step-up means for stepping up an input electromagnetic wave, a discharge electrode and a ground electrode forming a discharge gap,
A casing incorporating the input section and the discharge electrode, wherein the ground electrode is formed on the tip side,
The ignition device, wherein the casing is provided with a plurality of mounting holes for accommodating the input section and the discharge electrode.   The discharge electrode is formed at the tip of an electrode shaft portion extending from the bottomed tubular portion through the input shaft portion extending from the input portion to the side opposite to the input portion, and the tubular portion is formed into a tubular insulator. The ignition device according to claim 1, wherein the ignition device is disposed in the mounting hole in a state of being fitted.   The boosting means includes a first resonance region formed between the cylindrical portion and a casing covering the cylindrical portion, and a second resonance region formed between the electrode shaft portion and a casing covering the electrode shaft portion. 3. The ignition device according to claim 1, wherein the ignition device is configured.   4. The ignition device according to claim 3, wherein the booster is configured such that a resonance frequency is different for each of the mounting holes of the casing.

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