JP2018193872A - Ignition device - Google Patents

Abstract

To improve fuel economy.SOLUTION: An ignition device 200 includes: a power feeding-side electrode 230 having a confront surface 230a confronting a wall surface 130c forming a combustion chamber 140 while being separated apart from the wall surface; a spacer 210 constituted of an insulator and having a body 214 that is disposed between the wall surface 130c and the confront surface 230a of the power feeding-side electrode 230; and a high-frequency power source 240 for supplying high-frequency power to the power feeding-side electrode 230.SELECTED DRAWING: Figure 2

Description

  The present disclosure relates to an ignition device that ignites fuel supplied to a combustion chamber.

  Technologies have been developed that reduce NOx in exhaust gas and improve fuel efficiency by supplying a lean premixed gas into a cylinder (combustion chamber) constituting an engine and burning it. As a technique for igniting a lean premixed gas, a technique for introducing a flame generated in a sub chamber into a combustion chamber has been developed (for example, Patent Document 1).

JP 2006-132415 A

  However, the technique disclosed in Patent Document 1 has a problem in that fuel efficiency is reduced because fuel is combusted in the sub chamber.

  In view of such a problem, the present disclosure is intended to provide an ignition device capable of improving fuel consumption.

  In order to solve the above-described problem, an ignition device according to an aspect of the present disclosure is provided between a power feeding side electrode having a facing surface that is spaced apart and opposed to a wall surface, and the wall surface and the facing surface of the power feeding side electrode. And a spacer made of an insulator and a high-frequency power source for supplying high-frequency power to the power supply side electrode.

  Moreover, the said electric power feeding side electrode may have a flat plate-shaped main-body part and the protrusion part which protruded toward the outward from the outer edge of the said main-body part.

  Further, a depressed portion may be formed in the main body portion of the power supply side electrode, and the main body of the spacer may be accommodated in the depressed portion.

  The power supply side electrode may be disposed in an engine combustion chamber, and the wall surface may be provided on at least one of the engine cylinder head, the engine cylinder block, and the engine piston. Good.

  The wall surface may further include a medium flow path that accommodates the power supply side electrode, forms a housing space that communicates with a combustion chamber of the engine, and communicates with the housing space.

  The communication chamber may further include a communication hole that communicates with the combustion chamber and opens at least one of the cylinder head of the engine, the cylinder block of the engine, and the piston of the engine. .

  The ignition device according to the present disclosure can improve fuel consumption.

It is a figure explaining an engine. It is a figure explaining the ignition device concerning a 1st embodiment. FIG. 3A is a plan view showing the opposite surface side of the power supply side electrode. FIG. 3B is a plan view showing a surface side opposite to the facing surface of the power supply side electrode. It is a figure explaining the ignition device concerning 2nd Embodiment. It is the VV sectional view taken on the line of FIG. FIG. 6A is a diagram illustrating a modified spacer. FIG. 6B is an enlarged view of a region surrounded by a broken line in FIG.

  Hereinafter, an embodiment of the present disclosure will be described in detail with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values shown in the embodiment are merely examples for facilitating understanding, and do not limit the present disclosure unless otherwise specified. In the present specification and drawings, elements having substantially the same functions and configurations are denoted by the same reference numerals, and redundant description is omitted, and elements not directly related to the present disclosure are not illustrated. To do.

(First embodiment)
FIG. 1 is a diagram illustrating the engine 100. In the following drawings including FIG. 1 of this embodiment, the X axis, the Y axis, and the Z axis that intersect perpendicularly are defined as illustrated. As shown in FIG. 1, engine 100 includes a cylinder block 110, a piston 120, a connecting rod 122, a cylinder head 130, an intake valve 136, an exhaust valve 138, an injector 150, and an ignition device 200. Consists of.

  The cylinder block 110 is made of metal, and a plurality of cylinder bores 112 are formed. A piston 120 is slidably disposed in the cylinder bore 112. The piston 120 is connected to the connecting rod 122.

  The cylinder head 130 is made of metal and connected to the cylinder block 110. The cylinder head 130 is grounded. In engine 100, a space surrounded by cylinder bore 112, cylinder head 130, and crown surface 120 a of piston 120 is formed as combustion chamber 140.

  An intake port 132 and an exhaust port 134 are formed in the cylinder head 130. The intake port 132 and the exhaust port 134 communicate with the combustion chamber 140. The tip of the intake valve 136 is located between the intake port 132 and the combustion chamber 140. The tip of the exhaust valve 138 is located between the exhaust port 134 and the combustion chamber 140.

  The intake valve 136 is moved in the axial direction by an unillustrated intake camshaft. As a result, the intake valve 136 opens and closes between the intake port 132 and the combustion chamber 140. The exhaust valve 138 is moved in the axial direction by an unillustrated exhaust camshaft. As a result, the exhaust valve 138 opens and closes between the exhaust port 134 and the combustion chamber 140.

  The injector 150 injects fuel into the intake port 132. Therefore, an air-fuel mixture (pre-air mixture) of fuel and air is generated at the intake port 132. The premixed gas is supplied from the intake port 132 to the combustion chamber 140.

  The ignition device 200 ignites the fuel in the premixed gas in the combustion chamber 140 at a predetermined timing. As a result, the premixed gas is combusted in the combustion chamber 140. Due to this combustion, the piston 120 reciprocates, and the reciprocating motion is converted into a rotational motion of a crankshaft (not shown) through the connecting rod 122.

  FIG. 2 is a diagram illustrating the ignition device 200 according to the first embodiment. As shown in FIG. 2, the ignition device 200 includes a spacer 210, a power plug 220, a power supply side electrode 230, and a high frequency power source 240.

  The spacer 210 is formed of an insulator (dielectric material) such as ceramic, quartz glass, or resin (for example, Teflon (registered trademark)). The spacer 210 includes a cylindrical portion 212 and a main body 214. The cylinder part 212 is a cylindrical member. The cylinder portion 212 is inserted through a through hole 130 a formed in the cylinder head 130. In the present embodiment, the opening 130b of the through hole 130a is formed in the wall surface 130c between the intake port 132 and the exhaust port 134 (see FIG. 1). The tip of the cylinder part 212 is disposed in the combustion chamber 140. The main body 214 is a disk-shaped member that extends radially outward from the tip of the cylindrical portion 212. The main body 214 is disposed in the combustion chamber 140 with one surface 214a contacting the wall surface 130c. A surface 214b of the main body 214 opposite to the surface 214a is in contact with a depressed portion 232c of a power supply side electrode 230 described later.

  The power plug 220 is a cylindrical member made of metal. The power plug 220 is inserted into the cylindrical portion 212 of the spacer 210. That is, the power plug 220 is surrounded by the cylindrical portion 212. A high frequency power supply 240 is connected to one end of the power plug 220. The power supply side electrode 230 is connected to the other end side of the power plug 220. More specifically, a screw hole 222 is formed on the other end side of the power plug 220. The power supply side electrode 230 is connected (coupled) to the power plug 220 by screwing the screw 224 into the screw hole 222.

  The power supply side electrode 230 is made of metal, has a facing surface 230 a that is spaced apart from the wall surface 130 c, and is disposed in the combustion chamber 140. FIG. 3 is a diagram illustrating the shape of the power supply side electrode 230. FIG. 3A is a plan view showing the facing surface 230 a side of the power supply side electrode 230. FIG. 3B is a plan view showing the surface 230 b side opposite to the facing surface 230 a of the power supply side electrode 230.

  As shown in FIGS. 3A and 3B, the power supply side electrode 230 includes a main body portion 232 and a protruding portion 234. The main body 232 is a disk-shaped part. The main body 232 has an insertion hole 232a formed at the center. A screw 224 is inserted through the insertion hole 232a.

  As shown in FIG. 3A, a depressed portion 232 c is formed outside the insertion hole 232 a in the main body portion 232 on the opposing surface 230 a of the power supply side electrode 230. Further, as shown in FIG. 3B, a groove 232 b is formed outside the insertion hole 232 a in the main body 232 on the surface 230 b of the power supply side electrode 230. The head of the screw 224 comes into contact with the groove 232b. The size of the XY plane in FIG. 3B in the groove portion 232b is larger than the size of the head portion of the screw 224. The depth of the groove 232b (the length in the Z-axis direction in FIG. 3B) is equal to or higher than the height of the head of the screw 224.

  The protruding portion 234 is a portion protruding radially outward from the outer edge (outer periphery) of the main body portion 232. A plurality of protrusions 234 are provided on the outer periphery of the main body 232 so as to be spaced apart in the circumferential direction. The protruding portion 234 has a shape in which the area gradually decreases from the proximal end portion toward the distal end portion.

  Referring back to FIG. 2, the power supply side electrode 230 is connected to the power plug 220 such that the main body 214 of the spacer 210 is accommodated in the depressed portion 232 c formed in the main body portion 232. That is, the main body 232 has a larger outer edge (outer periphery) than the main body 214 of the spacer 210. Further, the depth D (the length in the Z-axis direction in FIG. 2) of the depressed portion 232 c is less than the thickness H of the main body 214. That is, the difference between the thickness H of the main body 214 and the depth D of the depressed portion 232c is the distance L between the power supply side electrode 230 and the wall surface 130c.

  As described above, the power supply side electrode 230 has the facing surface 230 a disposed in the combustion chamber 140 so as to face the wall surface 130 c with the main body 214 of the spacer 210 interposed therebetween.

  The high frequency power supply 240 supplies high frequency power to the power plug 220 (supplying a pulse voltage). Then, high frequency power is supplied to the power supply side electrode 230, and the cylinder head 130 functions as a ground side electrode. Thereby, non-equilibrium plasma is formed around the power supply side electrode 230 (dielectric barrier method).

  As described above, the ignition device 200 of this embodiment can form non-equilibrium plasma in the combustion chamber 140. Thereby, O radicals and OH radicals can be generated in the combustion chamber 140. O radicals and OH radicals have an effect of promoting ignition of fuel (hydrocarbon). For this reason, ignition can be performed at an early stage without using a dedicated fuel for ignition. Therefore, fuel consumption can be improved as compared with the prior art including a sub chamber.

  Further, in the ignition device 200, the main body 232 of the power supply side electrode 230 has a disk shape. Further, the wall surface 130 c that functions as the ground side electrode and the facing surface 230 a of the power feeding side electrode 230 face each other. That is, two electrodes forming plasma are opposed to each other in a plane. Thereby, planar plasma can be formed. That is, it becomes possible to form plasma in a wide range two-dimensionally. Therefore, the ignition speed can be improved as compared with the prior art that forms plasma in terms of points.

  Further, since the power supply side electrode 230 includes the protrusions 234, the plasma can be dispersed. Therefore, the ignition efficiency can be improved.

  In addition, since the spacer 210 includes the main body 214, the distance L between the main body portion 232 of the power supply side electrode 230 and the wall surface 130c can be extremely reduced. Thereby, even in the combustion chamber 140 in a high-density atmosphere (high-pressure atmosphere), plasma can be efficiently formed (discharged).

  The main body 232 includes a depressed portion 232c, and the main body 214 is accommodated in the depressed portion 232c. Thereby, damage to the main body 214 due to thermal expansion of the main body portion 232 can be prevented.

(Second embodiment: ignition device 300)
FIG. 4 is a diagram for explaining an ignition device 300 according to the second embodiment. As shown in FIG. 4, the ignition device 300 includes a spacer 210, a power plug 220, a power supply side electrode 230, a high frequency power supply 240, and a medium flow path 320. In addition, about the component substantially equivalent to the said ignition device 200, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  In the ignition device 300 of this embodiment, the main body 214 of the spacer 210 and the power supply side electrode 230 are accommodated in the accommodation space 310 that communicates with the combustion chamber 140 instead of the combustion chamber 140.

  The accommodation space 310 is a space formed in the cylinder head 130. The accommodation space 310 is partitioned by a first wall surface 310a, a second wall surface 310b, and a third wall surface 310c. The first wall surface 310a and the second wall surface 310b are circular. The first wall surface 310a and the second wall surface 310b face each other. The first wall surface 310 a faces the facing surface 230 a of the power supply side electrode 230. A through hole 130a is formed in the first wall surface 310a. The second wall surface 310b is formed with a communication hole 312 that allows the storage space 310 and the combustion chamber 140 to communicate with each other. That is, the back surface of the second wall surface 310 b becomes the wall surface 130 c of the combustion chamber 140. The third wall surface 310c is a surface that connects the first wall surface 310a and the second wall surface 310b.

  The communication hole 312 has a reduced diameter portion 312a and a small diameter portion 312b. One end of the reduced diameter portion 312a opens to the second wall surface 310b, and the other end continues to the small diameter portion 312b. The diameter of the reduced diameter portion 312a gradually decreases from one end to the other end. The small diameter portion 312b has one end continuous to the reduced diameter portion 312a and the other end opened to the wall surface 130c.

  The medium flow path 320 is a flow path that opens to the third wall surface 310 c and communicates with the accommodation space 310. Water (gas or liquid) is supplied to the medium flow path 320. Accordingly, water is supplied to the accommodation space 310 through the medium flow path 320.

  5 is a cross-sectional view taken along line VV in FIG. In FIG. 5, the flow of water is indicated by solid arrows. Further, in order to facilitate understanding in FIG. 5, the power supply side electrode 230 and the screw 224 are omitted.

  As shown in FIG. 5, the accommodation space 310 has a substantially circular XY cross section in FIG. 5. The opening 320a of the medium flow path 320 is formed in the third wall surface 310c. Therefore, the water supplied from the opening 320a flows along the tangential direction of the third wall surface 310c or along the third wall surface 310c. In other words, the position of the opening 320a is set so that water swirls at a high speed in the accommodation space 310. Therefore, the water that has passed through the medium flow path 320 swirls within the accommodation space 310.

  The water supplied to the accommodation space 310 by the medium flow path 320 is turned into plasma by the power supply side electrode 230 and the cylinder head 130 (grounding side electrode), and O radicals and OH radicals are generated. The O radicals and OH radicals thus generated are supplied to the combustion chamber 140 through the communication hole 312. Thereby, the fuel in the combustion chamber 140 can be ignited.

  Further, as described above, the communication hole 312 has the reduced diameter portion 312a and the small diameter portion 312b. That is, the communication hole 312 has a channel cross-sectional area that decreases from the accommodation space 310 toward the combustion chamber 140. Thereby, compared with the case where a communicating hole is the same diameter, the flow velocity of O radical and OH radical can be raised. Therefore, in the combustion chamber 140, O radicals and OH radicals can be diffused over a wide range, and the ignition efficiency can be improved.

(Modification)
FIG. 6A is a diagram illustrating a modified spacer 410. FIG. 6B is an enlarged view of a region surrounded by a broken line in FIG. As shown in FIG. 6A, the spacer 410 is formed of an insulator (dielectric material) and includes a cylindrical portion 212 and a main body 414. In addition, about the component substantially equivalent to the said ignition device 200,300, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 6A, the main body 414 includes a base 420 and a protrusion 422. The base 420 is a disk-shaped member that extends radially outward from the tip of the cylindrical portion 212. The base 420 is disposed in the combustion chamber 140 with one surface 420a contacting the wall surface 130c. The outer periphery (outer edge) of the base 420 is larger than the outer periphery (outer edge) of the main body 232 of the power supply side electrode 230. A protrusion 422 is provided on a surface 420b of the base 420 opposite to the surface 420a.

  The protrusion 422 has a cylindrical shape and protrudes from the center of the surface 420 a of the base 420 toward the main body 232 of the power supply side electrode 230. The outer periphery (outer edge) of the protrusion 422 is smaller than the outer periphery (outer edge) of the base 420. The protrusion 422 is accommodated in the depressed portion 232 c of the power supply side electrode 230. A front surface 422a of the protrusion 422 contacts the depressed portion 232c.

  As shown in FIG. 6B, the height T of the protrusion 422 (the distance from the base 420 to the surface 422a) T is greater than the depth D of the depression 232c. Therefore, a gap is formed between the surface 420b of the base 420 and the power supply side electrode 230 (back surface 230a). As described above, the outer periphery (outer edge) of the base 420 is larger than the outer periphery (outer edge) of the main body 232 of the power supply side electrode 230. For this reason, the back surface 230 a of the power supply side electrode 230 is arranged to face the surface 420 b of the base 420. That is, the base 420 (insulator) is disposed between the wall surface 130 c functioning as the ground side electrode and the power supply side electrode 230. Thereby, dielectric barrier type plasma can be generated, and plasma can be generated in a wide range two-dimensionally.

  As mentioned above, although embodiment was described referring an accompanying drawing, it cannot be overemphasized that this indication is not limited to this embodiment. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims and that they naturally fall within the technical scope.

  For example, in the above embodiment, the configuration in which the main body 232 of the power supply side electrode 230 has a disk shape has been described as an example. However, the shape of the main body 232 is not limited as long as the main body 232 has a wall surface 130c or a facing surface that faces the first wall surface 310a. The main body 232 may have a rectangular flat plate shape. In addition, irregularities may be formed on the surface 230 b of the power supply side electrode 230. Thereby, plasma can be dispersed.

  Further, in the above embodiment, the configuration in which the main body 214 of the spacer 210 has a disk shape has been described as an example. However, the shape of the main body 214 of the spacer 210 is not limited. The main body 214 may have a rectangular flat plate shape. The main body 214 may be disposed between the power supply side electrode 230 and the wall surface 130c functioning as the ground side electrode or the first wall surface 310a.

  Moreover, in the said embodiment, the structure which the electric power feeding side electrode 230 is provided with the protrusion part 234 was mentioned as an example, and was demonstrated. However, the protrusion 234 is not an essential configuration.

  Moreover, in the said embodiment, the structure by which the depression part 232c was formed in the main-body part 232 of the electric power feeding side electrode 230 was mentioned as an example, and was demonstrated. However, the depressed portion 232c is not an essential configuration.

  In the first embodiment, the configuration in which the facing surface 230a of the power supply side electrode 230 faces the wall surface 130c of the cylinder head 130 has been described as an example. However, the facing surface of the main body 232 of the power supply side electrode 230 may face the wall surface of the cylinder block 110. Specifically, among the wall surfaces forming the combustion chamber 140 in the cylinder block 110, the position above the top dead center of the piston 120 or the position facing the top dead center may be opposed to the facing surface of the main body 232. . Further, the facing surface of the main body 232 may face the crown surface 120 a of the piston 120.

  Moreover, in the said 2nd Embodiment, the communication hole 312 demonstrated and demonstrated the structure which opens to the wall surface 130c which forms the combustion chamber 140 in the cylinder head 130 as an example. However, if the communication hole 312 communicates with the combustion chamber 140, the opening position is not limited. The communication hole 312 may be opened, for example, in a wall surface that forms the combustion chamber 140 in the cylinder block 110. Specifically, the communication hole 312 may be opened above the top dead center of the piston 120 or at a position facing the top dead center on the wall surface forming the combustion chamber 140 in the cylinder block 110. Further, the communication hole 312 may be opened in the crown surface 120 a of the piston 120.

  The present disclosure can be used for an ignition device that ignites fuel supplied to a combustion chamber.

DESCRIPTION OF SYMBOLS 100 Engine 110 Cylinder block 120 Piston 130 Cylinder head 130c Wall surface 140 Combustion chamber 200 Ignition apparatus 210 Spacer 214 Main body 230 Power supply side electrode 230a Opposite surface 232 Main body part 232c Depression part 234 Projection part 240 High-frequency power source 300 Ignition apparatus 310 Accommodation space 312 Communication hole 320 Medium flow path

Claims (6)

A power feeding side electrode having a facing surface that is spaced apart from the wall surface and facing the
A spacer composed of an insulator having a main body disposed between the wall surface and the opposing surface of the power supply side electrode;
A high frequency power supply for supplying high frequency power to the power supply side electrode;
An ignition device comprising: The power supply side electrode is:
A plate-shaped main body,
A protrusion protruding outward from the outer edge of the main body,
The ignition device according to claim 1, comprising: The body portion of the power supply side electrode is formed with a depressed portion,
The ignition device according to claim 2, wherein the main body of the spacer is accommodated in the depressed portion.   The power supply side electrode is disposed in a combustion chamber of an engine, and the wall surface is provided in at least one of a cylinder head of the engine, a cylinder block of the engine, and a piston of the engine. The ignition device according to any one of 3. The wall surface accommodates the power supply side electrode and forms a housing space that communicates with a combustion chamber of the engine;
The ignition device according to any one of claims 1 to 3, further comprising a medium flow path communicating with the housing space.   6. The communication chamber according to claim 5, further comprising a communication hole communicating with the combustion chamber and the accommodation space and opening to at least one of a cylinder head of the engine, a cylinder block of the engine, and a piston of the engine. Ignition device.

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