JPH074248A - Auxiliary chamber type engine - Google Patents

Abstract

PURPOSE:To improve air utilizing rate in a main chamber and shorten a combustion period in the main chamber so as to improve thermal efficiency by leading jet of air injected from an auxiliary chamber into the main chamber through a communication hole. CONSTITUTION:A main chamber 1 is formed on a cylinder 3 side, an auxiliary chamber 2 is provided on nearly center axis of the cylinder 3 in a piston 8, a plurality of communication holes 4 for communicating the main chamber 1 and the auxiliary chamber 2 with each other are formed in their inclined state from the auxiliary chamber 2 toward a cylinder circumferential side, a fuel injection nozzle 10 is projected into the auxiliary chamber 2 in the vicinity of a top dead point through a center communication hole 15 formed in the center of the auxiliary chamber 2 upper part, and fuel is sprayed from the multiple injection hole 11 into the auxiliary chamber 2. The volume of the auxiliary chamber 2 is set to 60% or less of the whole volume with the piston on its top dead point, and a groove 30 extending to an outer side diameter direction and connected to the main chamber side opening part 12 of the communication hole 4 is formed on a piston top surface 37.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a subchamber engine having a main chamber, a subchamber communicating with the main chamber through a communication hole, and a fuel injection nozzle for injecting fuel into the subchamber.

[0002]

2. Description of the Related Art Conventionally, a swirl chamber type engine having a swirl chamber has been developed for the purpose of improving combustion of the engine. Such a swirl chamber engine has a swirl chamber formed in the cylinder head, a communication hole for communicating the swirl chamber with the main chamber formed on the cylinder side, and a fuel injection nozzle arranged in the swirl chamber. A mixture is formed with the fuel injected into the swirl chamber by the swirl flowing into the swirl chamber through the holes.

Japanese Utility Model Laid-Open No. 3-179127 discloses a direct combustion chamber structure for a direct injection diesel engine. The direct combustion chamber structure has a central opening and a peripheral opening formed in the center and peripheral portions of the piston top surface, and is formed inside the piston top surface so that the direct combustion chamber extends radially from the central opening toward the back. The peripheral openings communicate directly with the inner peripheral portion of the combustion chamber through the communication holes.

Further, Japanese Patent Laid-Open No. 63-176621 discloses a combustion chamber structure of an internal combustion engine. The combustion chamber structure is provided with at least one through hole and / or an annular slit that has an inclination with respect to the movement direction of the piston and that connects the piston top surface and the piston combustion chamber, and at least the vicinity of the through hole or the annular slit. Is composed of a ceramic member. Further, the inclination of the through hole or the annular slit with respect to the movement direction of the piston is formed in one direction or alternately in the opposite direction.

[0005]

[SUMMARY OF THE INVENTION Incidentally, direct-injection diesel engine is excellent in thermal efficiency compared to Fukushitsushiki diesel engines, many tracks have been used in an automobile such as a bus, of the NO _X It has a drawback that the production amount is large. On the other hand, the sub-chamber diesel engine is inferior in thermal efficiency to the direct injection diesel engine, but has an advantage that the amount of NO _x produced is small. The main reason why the sub-chamber engine is inferior in thermal efficiency to the direct injection engine is considered to be as follows. That is, (1) after the primary combustion in the sub chamber,
The flame is ejected through the communication port that communicates the main chamber and the sub chamber to carry out secondary combustion, which results in a longer combustion time.
(2) Occurrence of squeeze loss in the communication port that connects the main chamber and the sub chamber, and (3) because the air flow in the sub chamber is large,
The heat dissipation loss is large.

In the sub-chamber type engine, since the air-fuel mixture generation energy and the jetting energy, which are important for combustion, are formed by the throttle of the sub-chamber communication port, the passage area of the communication port cannot be increased, and therefore the pump is used. Since the loss is large and the air-fuel mixture is generated by vigorous air flow, the thermal conductivity in the sub chamber is large and the cooling water loss is large. Also, by providing a communication port that connects the main chamber and the sub chamber at an angle in the tangential direction of the wall of the sub chamber, the air flow in the sub chamber is activated, and after the ignition, the energy of the jet of flame into the main chamber is increased. Since the flame reaches the outermost circumference of the main chamber in a short time without any attenuation, the air utilization rate is improved, clean combustion with less harmful gas is possible, and the output is also improved. Also, in the case of a sub-chamber with an inclined sub-communication hole, the velocity of the passing air is the same at the time of inflow and at the time of ejection after ignition, under the condition that the influence of the intake inflow swirl in the main chamber is not considered. If you narrow the diameter of the contact port to increase energy,
At the same time, the air flow or swirl generated in the sub chamber also becomes stronger.

Further, in the swirl chamber type engine, since the communication port connecting the sub chamber and the main chamber is small, throttling loss occurs due to the communication port, which causes a reduction in engine output. Further, in general, since the communication port that connects the main chamber and the sub chamber is provided at either one of the center portion of the cylinder or the outer peripheral portion, the distance that the jet flow must reach becomes long, Mixing with air in the chamber becomes insufficient, HC,
It causes smoke. Further, since the communication port is narrowed and formed in an inclined state, the intake air flowing through the intake port forms a swirl flow in the cylinder, but when the swirl flow flows into the sub chamber through the communication port. However, there is a problem that the energy of the swirl flow cannot be fully utilized in the sub chamber.

Therefore, the present applicant has developed a sub-chamber engine that solves the above-mentioned problems, and filed a patent application as Japanese Patent Application No. 5-46175. The sub-chamber engine has a sub-combustion chamber configured as a cylinder head or a piston head, a main combustion chamber is formed on the cylinder side, and a plurality of communication ports that connect the main combustion chamber and the sub-combustion chamber are provided in the circumferential direction. optimizing by suppressing a swirl flow in the auxiliary combustion chamber, to prevent heat dissipation from the auxiliary combustion chamber to the outside, to reduce the throttle loss of the communication port, is burned in the fuel-rich to suppress the generation of NO _X, Further, the auxiliary combustion chamber is arranged in the center of the cylinder, and the reaching distance of the jet flow ejected from the auxiliary combustion chamber to the main combustion chamber through the communication port is shortened, and the jet flow from the auxiliary combustion chamber to the main combustion chamber is shortened. Swirl flow formed in the sub-combustion chamber and jet in the forward flow direction,
Utilizing swirl flow existing in the main combustion chamber to promote mixing of the fresh air in the main combustion chamber, to improve the performance by shortening the combustion period, intended to suppress smoke, HC, and occurrence of NO _X is there.

An object of the present invention is to form a main chamber on the cylinder side, provide a sub chamber substantially on the central axis of the cylinder of the piston, and provide a communication hole for communicating the main chamber and the sub chamber from the sub chamber to the cylinder. A plurality of fuel injection nozzles are formed to be inclined toward the peripheral side, and a fuel injection nozzle is projected into a central communication hole formed in the center of the upper portion of the sub chamber near the top dead center to spray fuel into the sub chamber from multiple injection holes of the fuel injection nozzle. A chamber type engine is provided, and in particular, a mixture gas jetted from the sub chamber to the main chamber through the communication hole reaches the outer periphery of the cylinder by penetrating to reach the outer periphery of the cylinder, and the jet flow is mixed with air in the main chamber. To provide a sub-chamber engine in which the shape of the main chamber is optimized to promote combustion.

Another object of the present invention is to form a main chamber on the cylinder side, provide a sub chamber substantially on the center axis of the cylinder of the cylinder head, and provide a communication hole for communicating the main chamber and the sub chamber with each other. Provided is a sub-chamber engine in which a plurality of chambers are formed so as to incline toward a cylinder peripheral side, and fuel is sprayed into the sub chamber from multiple injection holes of a fuel injection nozzle, and particularly, the main chamber is provided from the sub chamber through the communication hole. The air-fuel mixture ejected to the cylinder reaches the outer periphery of the cylinder by penetrating it to reach the outer periphery of the cylinder, and promotes the mixing of the jet flow with the air in the main chamber to burn the air-fuel mixture. It is to provide a room type engine.

[0011]

In order to achieve the above object, the present invention is configured as follows. That is, according to the present invention, a cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a piston provided on substantially the central axis of the cylinder of the piston. A sub-chamber, a plurality of communication holes communicating the main chamber and the sub-chamber and inclined from the sub-chamber toward the cylinder peripheral side, and a central communication hole formed in the center of the upper portion of the sub-chamber near the top dead center. In a sub-chamber engine having a fuel injection nozzle having multiple injection holes for plunging and spraying fuel into the sub-chamber, the volume of the sub-chamber is set to 60% or less of the total volume at the piston top dead center, The auxiliary chamber engine is characterized in that a groove extending in the outer radial direction is formed on the top surface so as to connect to the main chamber side opening of the communication hole.

In this sub-chamber engine, the piston peripheral portion of the groove is bent in the direction of the intake swirl remaining in the main chamber.

Alternatively, according to the present invention, a cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a piston substantially on the central axis of the cylinder. A sub-chamber, a plurality of communication holes that connect the main chamber and the sub-chamber and are inclined from the sub-chamber toward the cylinder peripheral side, and a central communication hole formed in the upper center of the sub-chamber. In a sub-chamber engine having a fuel injection nozzle having a multi-injection hole that rushes in the vicinity of a point and sprays fuel into the sub-chamber, the cylinder head lower surface is outside from a position corresponding to the main chamber side opening of the communication hole. The present invention relates to a sub-chamber engine having a groove extending in the radial direction.

Alternatively, according to the present invention, a cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a piston substantially on the central axis of the cylinder. A sub-chamber, a plurality of communication holes that connect the main chamber and the sub-chamber and are inclined from the sub-chamber toward the cylinder peripheral side, and a central communication hole formed in the upper center of the sub-chamber. In a sub-chamber engine having a fuel injection nozzle having a multi-injection hole that rushes in the vicinity of a point and sprays fuel into the sub-chamber, in the main chamber side opening of the communication hole on the piston top surface, the cylinder head lower surface A cavity serving as a clearance is formed between them, and a groove is formed on the lower surface of the cylinder head and extends from the position corresponding to the opening on the main chamber side of the communication hole to branch outward in the radial direction. For the auxiliary chamber type engine, characterized in that.

Alternatively, according to the present invention, a cylinder head mounted on a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a piston substantially on the central axis of the cylinder. A sub-chamber, a plurality of communication holes that connect the main chamber and the sub-chamber and are inclined from the sub-chamber toward the cylinder peripheral side, and a central communication hole formed in the upper center of the sub-chamber. In a sub-chamber engine having a fuel injection nozzle having a multi-injection hole that rushes in the vicinity of a point and sprays fuel into the sub-chamber, in the main chamber side opening of the communication hole on the piston top surface, the cylinder head lower surface A cavity serving as a clearance is formed between the guide holes, and a guide protrusion is formed on the lower surface of the cylinder head and extends radially outward from a position corresponding to the opening on the main chamber side of the communication hole. For the auxiliary chamber type engine, wherein it is.

Alternatively, according to the present invention, a cylinder head mounted on a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a substantially center of the cylinder of the cylinder head. In a sub-chamber engine having a sub-chamber provided on a shaft, a plurality of communication holes communicating the main chamber and the sub-chamber, and a fuel injection nozzle for spraying fuel into the sub-chamber, the communication hole is the sub-chamber. From the position corresponding to the opening on the main chamber side of the communication hole, a groove is formed to branch radially from the piston periphery to the piston top surface. And the sub-chamber engine.

Alternatively, according to the present invention, a cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a substantially center of the cylinder of the cylinder head. In a sub-chamber engine having a sub-chamber provided on a shaft, a plurality of communication holes communicating the main chamber and the sub-chamber, and a fuel injection nozzle for spraying fuel into the sub-chamber, the communication hole is the sub-chamber. From the position corresponding to the opening on the main chamber side of the communication hole, a guide projection is formed to extend radially outward from the position corresponding to the main chamber side opening of the communication hole. And the sub-chamber engine.

[0018]

The subchamber engine according to the present invention is configured as described above and operates as follows. That is, in this sub-chamber engine, a main chamber is formed on the cylinder side, a sub-chamber is provided substantially on the central axis of the cylinder of the piston, and a communication hole that connects the main chamber and the sub-chamber is provided from the sub-chamber to the cylinder. A plurality of fuel injection nozzles are formed so as to be inclined toward the peripheral side, and a fuel injection nozzle is projected into a central communication hole formed in the upper center of the sub chamber near the top dead center to spray fuel into the sub chamber from multiple injection holes of the fuel injection nozzle. In particular, the volume of the sub chamber is set to 60% or less of the total volume at the top dead center of the piston, and the piston top surface has a groove extending in the outer radial direction connected to the main chamber side opening of the communication hole. Therefore, the air-fuel mixture ejected from the sub chamber to the main chamber through the communication hole has a small passage area of one of the communication holes and can reach the outer periphery of the cylinder by extending the penetration. Improve the utilization rate of the jet and the main Can improve the thermal efficiency by shortening the combustion period expediting combustion speed mixing is promoted with the air of the inner. Further, the distance between the communication hole and the cylinder wall surface is short, the arrival distance of the jet flow from the communication hole is short, the combustion speed is fast, and the efficiency is improved. Further, since the jet can reach a short distance from the sub-chamber, a plurality of the communication holes can be formed to increase the passage area of the communication holes, reducing the squeezing loss and improving the efficiency.
Furthermore, by providing a plurality of the communication holes, the range of the main chamber for the combustion gas such as flames and unburned air-fuel mixture ejected from one communication hole is narrowed, the mixing with the fresh air is promoted, and the combustion is combusted. Speed is reduced.

Further, in this sub-chamber engine, since the piston peripheral portion of the groove is bent in the direction of the intake swirl remaining in the main chamber, the jet flow from the communication hole causes a swirl flow in the main chamber. When the jet flow is generated, the jet flow and the air in the main chamber are mixed with each other to accelerate the combustion speed, shorten the combustion period, and improve the thermal efficiency.

Alternatively, in this sub-chamber engine, since the groove that extends radially outward from the position corresponding to the main chamber side opening of the communication hole is formed on the lower surface of the cylinder head, the piston top surface as described above. As in the case of forming grooves in the cylinder, it is possible to reach by extending the penetration to the outer periphery of the cylinder, improve the air utilization rate and promote the mixing of the jet flow with the air in the main chamber to accelerate the combustion speed and increase the combustion period. Can be shortened to improve thermal efficiency.

Alternatively, in this sub-chamber engine, a cavity serving as a clearance between the piston top surface and the lower surface of the cylinder head is formed in the opening of the communication hole on the main chamber side, and the lower surface of the cylinder head is provided with the cavity. Since a groove is formed that branches outward in the radial direction from the position corresponding to the main chamber side opening, the jet flow from the communication hole is greater than that in the case where the groove is formed on the lower surface of the cylinder head as described above. Are further diffused in the main chamber, promoting the mixing of the jet flow and fresh air, improving the air utilization rate and promoting the mixing of the jet flow with the air in the main chamber to accelerate the combustion speed and shorten the combustion period. The thermal efficiency can be improved.

Alternatively, in this sub chamber type engine, a cavity serving as a clearance between the piston top surface and the lower surface of the cylinder head is formed in the main chamber side opening of the communication hole, and the communication hole is formed on the lower surface of the cylinder head. Since a guide convex portion that expands radially outward from a position corresponding to the main chamber side opening of the is formed, the jet flow ejected from the communication hole to the main chamber is generated in the main chamber by the guide convex portion. It is well diffused in a short period of time and promotes the mixing of the jet flow and fresh air to accelerate the combustion speed and shorten the combustion period to improve the thermal efficiency.

Alternatively, in this sub-chamber engine, a main chamber is formed on the cylinder side, the sub-chamber is provided substantially on the center axis of the cylinder of the cylinder head, and the communication hole for communicating the main chamber and the sub-chamber is provided. Provided is a sub-chamber engine in which a plurality of sub-chambers are formed so as to be inclined toward the cylinder peripheral side, and fuel is sprayed into the sub-chamber from multiple injection holes of a fuel injection nozzle, and in particular, the communication hole is provided from the sub-chamber to the cylinder. Since the groove is formed so as to be inclined toward the peripheral side and the piston top surface is formed with a groove that extends in a radial direction around the piston from a position corresponding to the main chamber side opening of the communication hole, as described above. Similarly to the case where the branch groove is formed on the lower surface of the cylinder head, the jet flow from the communication hole further diffuses in the main chamber, promoting the mixing of the jet flow and fresh air,
It is possible to improve the air utilization rate, promote the mixing of the jet flow and the air in the main chamber, accelerate the combustion speed, shorten the combustion period, and improve the thermal efficiency.

Further, in this sub-chamber engine, in particular, the communication hole is formed so as to be inclined from the sub-chamber toward the cylinder peripheral side, and the piston top surface corresponds to the main chamber side opening of the communication hole. Since the guide protrusions are formed to extend radially outward from the position, as described above, like the guide protrusions formed on the lower surface of the cylinder head, jetting from the communication hole to the main chamber is performed. The generated jet flow is favorably diffused in the main chamber in a short period of time by the guide convex portion, promotes mixing of the jet flow and fresh air, accelerates combustion speed, shortens combustion period, and improves thermal efficiency.

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a subchamber engine according to the present invention will be described below with reference to the drawings. 1 is a sectional view showing an embodiment of a sub-chamber engine according to the present invention, and FIG. 2 is a plan view showing a piston top surface of the sub-chamber engine of FIG.

This sub-chamber engine includes a cylinder block 6 made of a metal material such as aluminum, an aluminum alloy and cast iron, and a cylinder head made of a metal material such as an aluminum alloy fixed to the cylinder block 6 with a gasket 32 interposed therebetween. Have five. Cylinder block 6
The cylinder 3 is formed with holes corresponding to the number of cylinders of the engine, and the cylinder liner forming the cylinder 3 is fitted into the holes. Further, the cylinder head 5 is formed with an intake port 13 and an exhaust port 17 corresponding to each cylinder 3, and an intake valve 16 is arranged in a valve seat of the intake port 13, and the exhaust port 17 is provided.
An exhaust valve 26 is arranged in the valve seat of the. A piston 8 is incorporated in the cylinder 3 formed in the cylinder liner so as to reciprocate. The main chamber 1 is formed on the cylinder 3 side between the cylinder head lower surface 14 and the piston top surface 37. In addition, the sub chamber 2 has a piston 8
It is composed of a cavity 22 formed in the piston head portion 9 of the above, and is provided substantially on the central axis of the cylinder 3.
The fuel injection nozzle 10 provided on the cylinder head 5 is
It has multiple injection holes 11 and is configured to inject fuel into the sub chamber 2.

This sub-chamber engine uses alcohol fuel,
This is a diesel engine that injects liquid fuel such as light oil from the fuel injection nozzle 10 into the sub chamber 2 and burns it. The sub chamber 2 is formed on the piston head 9 side, and the piston head 9
A plurality of communication holes 4 (six in FIG. 2) are provided. The communication hole 4 which connects the main chamber 1 and the sub chamber 2 is formed from the sub chamber 2 to the main chamber 1.
That is, a plurality of cylinders are formed radially around the cylinder and inclined. Regarding the sub chamber 2 formed in the piston head portion 9, the volume ratio of the sub chamber 2 to the total combustion chamber volume at the piston top dead center is set to about 60% or less. The communication holes 4 are formed in the piston head portion 9 so as to be spaced from the center of the sub chamber 2 in the circumferential direction and to be inclined in the cylinder peripheral direction from the sub chamber side opening 18 to the main chamber side opening 12. . The fuel injection nozzle 10 projects into the central communication hole 15 formed in the center of the sub chamber of the piston head portion 9 near the top dead center of the compression stroke of the piston 8 and can inject fuel from the multiple injection holes 11 into the sub chamber 2. It is a thing.

This sub-chamber engine has a fuel injection nozzle 1
The central communication hole 1 formed in the piston head portion 9 at the center of the upper portion of the sub chamber has a diameter slightly larger than the outer diameter of the fuel injection nozzle 10 so that 0 can enter near the top dead center of the piston.
Have five. In this sub-chamber engine, in particular, the piston top surface 37 is formed with a groove 30 that is connected to the main chamber side opening 12 of the communication hole 4 and extends in the outer radial direction. Moreover, the piston peripheral portion of these grooves 30 is formed on the curved surface 33 that is curved in the same circumferential direction, and these curved surfaces 33 act to swirl each jet in the main chamber 1. In particular, the bending of the groove 30 around the piston is
When bent in the direction of the intake swirl remaining in the main chamber 1, the curved surface serves as a guide for the jet flow, and the jet flow can ride on the intake swirl to promote mixing. Also, the groove 3
In the vicinity of the end on the cylinder peripheral side of 0, it is preferable that the tapered surface (see FIG. 1) or the radius R (see FIG. 4) is formed so that the penetration can be extended without reducing the ejection energy.

In general, the communication hole provided in the radial direction has a small clearance between the top surface of the piston and the bottom surface of the cylinder head when the piston is located at the top dead center TDC. The effective area is regulated by the size of the clearance, and the effective area becomes small. On the other hand, in this sub-chamber engine, since the groove 30 is formed on the piston top surface 37 in communication with the main chamber side opening 12 of the communication hole 4, the jet is ejected from the communication hole 4 even at the piston top dead center TDC. It is possible to secure an effective area for the jet flow. That is, each groove 30 formed on the piston top surface 37 guides or guides flames, unburned air-fuel mixture, and other gases ejected from the sub chamber 2 to the main chamber 1 through the communication hole 4 to the cylinder outer periphery, that is, the cylinder peripheral portion, Combustion in the main chamber 1 can be performed from the periphery of the cylinder with a large amount of air, and the fresh air remaining in the main chamber 1 can be used effectively and the air utilization rate can be increased.

The graph shown in FIG. 3 shows the relationship between the groove length and the output in the subchamber engine of FIG.
FIG. 4 is an explanatory diagram showing the relationship between the groove length and the cylinder bore radius in the subchamber engine of FIG. As shown in FIG. 4, the cylinder bore radius is indicated by the symbol A, and the length of the groove 30 formed in the piston top surface 37 is indicated by the symbol B. In FIG. 3, the horizontal axis represents the ratio A / B of the cylinder bore radius A and the length B of the groove 30, and the vertical axis represents the output%. Ratio A / B
In the state of 0.2, the maximum output can be achieved. When the ratio A / B is 0, the groove 30 is not formed. As can be seen from FIG. 3, the length B of the groove 30 is
When the ratio A / B is in the range of 0.1 to 0.3, it is effective for increasing the output, and the most preferable state is 0.2. However, when the ratio A / B becomes 0.4, the output becomes equivalent to the state without the groove, but when the length B of the groove 30 becomes long, the jet flow ejected from the communication hole 4 reaches the cylinder wall surface to the cylinder 1 side. It is considered that the fuel has arrived without mixing with the air inside, and on the contrary, combustion has deteriorated.

Next, another embodiment of the sub-chamber engine according to the present invention will be described with reference to FIGS. FIG. 5 shows another embodiment of the sub-chamber engine according to the present invention and is a cross-sectional view taken along the line CC in FIG. 6, and FIG. 6 is an explanatory view showing the lower surface of the cylinder head of the sub-chamber engine in FIG. This embodiment has the same structure as that of the embodiment shown in FIG. 1 except that the groove is formed on the lower surface of the cylinder head. Therefore, the same parts are designated by the same reference numerals, A duplicate description will be omitted.

This sub-chamber engine has a cylinder head 5 attached to a cylinder block 6 constituting a cylinder 3, a piston 8 which reciprocates in the cylinder 3, a main chamber 1 formed on the cylinder 3 side, and a cylinder of a piston 8. In the sub-chamber 2, a sub-chamber 2 provided substantially on the central axis of the sub-chamber 3, a plurality of communication holes 4 communicating the main chamber 1 and the sub-chamber 2 and inclined from the sub-chamber 2 toward the cylinder peripheral side. Multiple injection holes 11 for spraying fuel
The fuel injection nozzle 10 having In this sub-chamber engine, the fuel injection nozzle 1 is provided at the center of the upper portion of the sub-chamber.
A central communication hole 15 in which 0 is inserted near the top dead center is formed, and the diameter of the central communication hole 15 is formed to be slightly larger than the outer diameter of the fuel injection nozzle 10. In this sub-chamber engine, in particular, a groove 28 extending radially outward from a position corresponding to the main chamber side opening 12 of the communication hole 4 is formed on the lower surface 14 of the cylinder head. The groove 28 is arranged between the intake and exhaust valves 16 and 26 and extends radially toward the cylinder peripheral side.

This sub-chamber engine has substantially the same operation as the above embodiment. Particularly, in this sub-chamber engine, since the groove 28 is provided in the head lower surface 14 of the cylinder head 5, gases such as flames and unburned air-fuel mixture extend radially from the sub-chamber 2 in the cylinder peripheral direction.
Is ejected to the main chamber 1 side through the groove 28, and is guided to the groove 28, is guided to the cylinder peripheral side while promoting the mixing with the fresh air in the main chamber 1, and the air and the jet flow are formed in the outer peripheral portion of the cylinder where the air amount is large. Mixing is achieved in a short period of time, shortening the combustion period and completing the combustion. Therefore, in this pre-combustion chamber engine, it improves thermal efficiency, while reducing fuel consumption, NO _X and carbon, smoke, the generation of particulates such as HC can be suppressed. Further, in this sub-chamber engine, since the groove 28 is formed in the head lower surface portion 14 of the cylinder head 5, the piston head portion 9 of the piston 8 is flattened with the ceramic top surface 37 such as Si ₃ N _4. It is preferable to apply it to the surface.

Next, with reference to FIGS. 7 and 8, another embodiment of the sub-chamber engine according to the present invention will be described. FIG. 7 is a sectional view showing still another embodiment of the sub-chamber engine according to the present invention, and FIG. 8 is an explanatory view showing the lower surface of the cylinder head of the sub-chamber engine of FIG. This embodiment has the same configuration as that of the embodiment shown in FIG. 5 except that the shape of the groove on the lower surface of the cylinder head is different. Therefore, the same parts are designated by the same reference numerals and duplicated. The description will be omitted.

In this sub-chamber engine, a cylinder head 5 is attached to a cylinder block 6 constituting a cylinder 3, and a piston 8 is incorporated so as to reciprocate in the cylinder 3. The main chamber 1 is formed on the cylinder 3 side,
In the piston head portion 9 of the piston 8, a cavity 22 that forms the sub chamber 2 is formed substantially on the central axis of the cylinder 3. A plurality of communication holes 4 that communicate the main chamber 1 and the sub chamber 2 are formed in the piston head portion 9, and each communication hole 4 is formed so as to be radially inclined from the sub chamber 2 to the cylinder peripheral side. Further, a fuel injection nozzle 10 having multiple injection holes 11 is attached to the cylinder head 5, and the fuel injection nozzle 10 projects into a central communication hole 15 formed in the center of the upper portion of the sub chamber near the top dead center. The fuel is sprayed from the multiple injection holes 11 into the sub chamber 2. The diameter of the central communication hole 15 into which the fuel injection nozzle 10 projects is formed to be slightly larger than the outer diameter of the fuel injection nozzle 10.

In this sub-chamber engine, in particular, a cavity 36 is formed in the piston top surface 37 at the main chamber side opening 12 of the communication hole 4 to form a clearance with the cylinder head lower surface 14, and the cylinder head lower surface is formed. 14 is formed with a branch groove 29 that is branched and extends outward in the radial direction from a position corresponding to the main chamber side opening 12 of the communication hole 4. This sub-chamber engine forms an air flow in the sub-chamber 2 by the air that obliquely flows into the sub-chamber 2 from the main chamber 1 through the communication hole 4 in the compression stroke, and fuel is injected during the air flow. Fuel is injected from the multiple injection holes 11 of the nozzle 10. Therefore, the air and the fuel spray are mixed in a short period of time and ignite and burn. At this time, the formation of the communication holes 4 is set so that the air flow generated in the sub chamber 2 has an optimum value.

Next, the combustible air-fuel mixture in the sub-chamber 2 is jetted into the main chamber 1 through the communication hole 4, but a cavity 36 which forms a clearance is formed in the piston top surface 37.
Moreover, since a branch groove 29 (branch 29 is divided into three in FIG. 8) is formed on the head lower surface 14 of the cylinder head 5, the jet flow ejected into the main chamber 1 through the communication hole 4 is branched. Is ejected to the cylinder periphery side in a short time and diffuses to the whole area of the main chamber, and the mixing of the fresh air in the main chamber 1 with gas such as flame and unburned mixture is achieved in a short time, and the combustion period is Shorten, improve thermal efficiency, reduce fuel consumption, N
O _X and the carbon, smoke, the generation of particulates such as HC can be suppressed.

Next, another embodiment of the sub-chamber engine according to the present invention will be described with reference to FIGS. Figure 9
Is a sectional view showing another embodiment of the sub-chamber engine according to the present invention, and FIG. 10 is an explanatory view showing the lower surface of the cylinder head of the sub-chamber engine of FIG. This embodiment has the same configuration as that of the embodiment shown in FIG. 5 except that a convex portion is provided on the lower surface of the cylinder head instead of the groove. Therefore, the same parts are designated by the same reference numerals. And redundant description will be omitted.

This sub-chamber engine has a cylinder head 5 attached to a cylinder block 6 constituting a cylinder 3, a piston 8 which reciprocates in the cylinder 3, a main chamber 1 formed on the cylinder 3 side, and a cylinder of a piston 8. In the sub-chamber 2, a sub-chamber 2 provided substantially on the central axis of the sub-chamber 3, a plurality of communication holes 4 communicating the main chamber 1 and the sub-chamber 2 and inclined from the sub-chamber 2 toward the cylinder peripheral side. Multiple injection holes 11 for spraying fuel
The fuel injection nozzle 10 having In this sub-chamber engine, the fuel injection nozzle 1 is provided at the center of the upper portion of the sub-chamber.
A central communication hole 15 in which 0 is inserted near the top dead center is formed, and the diameter of the central communication hole 15 is formed to be slightly larger than the outer diameter of the fuel injection nozzle 10.

In this sub-chamber engine, in particular, a cavity 36, which is a clearance between the piston top surface 37 and the head lower surface 14 of the cylinder head 5, is formed in the main chamber side opening 12 of the communication hole 4, and the head lower surface is formed. 14 is formed with a guide convex portion 40 that extends outward in the radial direction from a position corresponding to the main chamber side opening 12 of the communication hole 4. These guide convex portions 40 have a function of diffusing the jet flow ejected from the communication hole 4 into the main chamber 1 in a wide range. This sub-chamber engine can achieve almost the same function as the sub-chamber engine shown in FIG. 7, but the jet flow ejected collides with the guide convex portion 40 and diffuses into the main chamber 1 in a short period of time. Promotes mixing with air. Therefore, in this sub-chamber engine, the mixing of the fresh air in the main chamber 1 with the gas such as flame and unburned mixture is achieved in a short period of time, the combustion period is shortened, the thermal efficiency is improved, and the output is increased. As a result, it is possible to reduce fuel consumption and suppress the generation of NO _X and particulates such as carbon, smoke and HC.

Next, with reference to FIGS. 11 and 12, another embodiment of the sub-chamber engine according to the present invention will be described. FIG. 11 is a sectional view showing still another embodiment of the sub-chamber engine according to the present invention, and FIG. 12 is an explanatory view showing a piston top surface of the sub-chamber engine of FIG. This embodiment has the same structure as the embodiment shown in FIG. 1 except that the sub chamber is provided in the cylinder head and the groove formed on the piston top surface is formed in the branch groove, and therefore the same construction as that of the embodiment shown in FIG. The parts having the function are denoted by the same reference numerals, and the duplicated description will be omitted.

This sub-chamber engine has a cylinder head 5 attached to a cylinder block 6 constituting a cylinder 3, a piston 8 that reciprocates in the cylinder 3, a main chamber 1 formed on the cylinder 3 side, and a cylinder head 5. Has a sub-chamber 2 provided substantially on the central axis of the cylinder 3, a plurality of communication holes 4 communicating the main chamber 1 and the sub-chamber 2, and a fuel injection nozzle 10 for spraying fuel into the sub-chamber 2. There is. In this sub-chamber engine, in particular, the communication hole 4 is formed so as to radially incline from the sub-chamber 2 to the cylinder peripheral side of the main chamber 1, and the main chamber side opening 12 of the communication hole 4 is formed on the piston top surface 37. That is, a branch groove 41 is formed to branch from the position corresponding to the above to the radial direction around the piston. Note that, in FIG. 11, the intake / exhaust ports formed in the cylinder head 5 and the intake / exhaust valves arranged in the intake / exhaust ports are not shown.

This sub-chamber engine has substantially the same operation as the sub-chamber engine shown in FIG. That is, this sub-chamber engine has a piston top surface 3
7 is formed with a branch groove 41 that branches (in FIG. 12, the groove 41 is branched into three), so that the main chamber 1
The jet flow ejected to the branch groove 41 is ejected to the peripheral side of the cylinder for a short period of time, diffuses in the whole area of the main chamber, and mixes with the fresh air in the main chamber 1 and a gas such as a flame or an unburned mixture. Can be achieved in a short period of time, the combustion period can be shortened, the thermal efficiency can be improved, the fuel consumption can be reduced, and the generation of NO _X and particulates such as carbon, smoke and HC can be suppressed.

Next, another embodiment of the subchamber engine according to the present invention will be described with reference to FIGS. 13 is a sectional view showing another embodiment of the sub-chamber engine according to the present invention, and FIG. 14 is an explanatory view showing a piston top surface of the sub-chamber engine of FIG. This embodiment has the same configuration as that of the embodiment shown in FIG. 11 except that a guide protrusion is provided on the top surface of the piston instead of a groove. The same reference numerals are given and duplicated description is omitted.

This sub-chamber engine has a cylinder head 5 attached to a cylinder block 6 constituting a cylinder 3, a piston 8 reciprocating in the cylinder 3, a main chamber 1 formed on the cylinder 3 side, and a cylinder head 5. Of the sub-chamber 2 provided substantially on the central axis of the cylinder 3, a plurality of communication holes 4 communicating the main chamber 1 and the sub-chamber 2, and a fuel injection that is attached to the cylinder head 5 and sprays fuel into the sub-chamber 2. It has a nozzle 10. In this sub-chamber engine, in particular, the communication hole 4 is formed so as to be radially inclined from the sub-chamber 2 toward the cylinder peripheral side, and the piston top surface 37 is located outside the position corresponding to the main chamber side opening 12 of the communication hole 4. That is, the guide convex portion 42 that is enlarged in the radial direction and extends is formed. In addition, in FIG. 13, the intake / exhaust port formed in the cylinder head 5 and the intake / exhaust valve arranged in the intake / exhaust port are not shown.

This sub-chamber engine has substantially the same operation as the sub-chamber engine shown in FIG. That is, in this sub-chamber engine, since the guide convex portion 42 is formed on the piston top surface 37, the jet flow ejected from the sub-chamber engine 2 into the main chamber 1 through the communication hole 4 is guided to the guide convex portion 42. It collides, diffuses, and diffuses in the whole area of the main chamber in a short time, and the mixing of the fresh air with the gas such as flame and unburned mixture in the main chamber 1 is achieved in a short time, shortening the combustion period and improving the thermal efficiency. It is possible to improve and reduce fuel consumption, and to suppress the generation of NO _X and particulates such as carbon, smoke and HC.

[0047]

The subchamber engine according to the present invention is constructed as described above and has the following effects. In this sub-chamber engine, a main chamber is formed on the cylinder side, a sub-chamber is provided substantially on the central axis of the cylinder of the piston, and a communication hole that connects the main chamber and the sub-chamber is provided from the sub-chamber to the peripheral side of the cylinder. A plurality of fuel injection nozzles are formed to incline toward the center communication hole formed in the center of the upper portion of the sub chamber near the top dead center to spray fuel into the sub chamber from the multiple injection holes of the fuel injection nozzle.
In particular, the volume of the sub chamber is 6 times the total volume at the piston top dead center.
Since it is set to 0% or less and a groove extending in the outer radial direction is formed on the top surface of the piston and connected to the opening of the communication hole on the main chamber side, it is jetted from the sub chamber to the main chamber through the communication hole. The air-fuel mixture has a small passage area for one of the communication holes and can reach the outer circumference of the cylinder by extending the penetration, thereby improving the air utilization rate in the main chamber and improving the jet flow and the fresh air in the main chamber. The mixture is accelerated in a short time to accelerate the combustion speed to shorten the combustion period to improve the thermal efficiency, improve the output to reduce the fuel consumption, and suppress the generation of particulates such as NO _X, HC, carbon and smoke. can do.

Further, the distance between the communication hole and the cylinder wall surface is short, the arrival distance of the jet flow from the communication hole is short, the combustion speed is fast, and the efficiency is improved. Furthermore, since the jet can reach a short distance from the sub chamber, it is possible to form a plurality of the communication holes to increase the passage area thereof, reduce the squeezing loss, and improve the efficiency. Further, by providing a plurality of the communication holes, a flame ejected from one communication hole,
The range of the main chamber that is occupied by the combustion gas such as unburned air-fuel mixture is narrowed, the mixing with fresh air is promoted, and the combustion speed is shortened.

Further, in this sub-chamber engine, since the piston peripheral portion of the groove is formed into a curved surface which is curved in the direction of the intake swirl remaining in the main chamber, the jet flow ejected from the communication hole is , Guided by the groove and then guided by the curved surface to generate a swirl flow in the main chamber, promoting the mixing of the jet flow and air in the main chamber to accelerate the combustion speed and shorten the combustion period. The thermal efficiency can be improved.

Alternatively, in this sub-chamber engine, since the groove that extends radially outward from the position corresponding to the main chamber side opening of the communication hole is formed on the lower surface of the cylinder head, the piston top surface as described above. As in the case of forming grooves in the cylinder, it is possible to reach by extending the penetration to the outer periphery of the cylinder, improve the air utilization rate and promote the mixing of the jet flow with the air in the main chamber to accelerate the combustion speed and increase the combustion period. Can be shortened to improve thermal efficiency.

Alternatively, in this sub-chamber engine, a cavity serving as a clearance between the piston top surface and the lower surface of the cylinder head is formed at the opening of the communication hole on the main chamber side, and the lower surface of the cylinder head is provided with the cavity. Since a groove is formed that branches outward in the radial direction from the position corresponding to the main chamber side opening, the jet flow from the communication hole is greater than that in the case where the groove is formed on the lower surface of the cylinder head as described above. Are further diffused in the main chamber, promoting the mixing of the jet flow and fresh air, improving the air utilization rate and promoting the mixing of the jet flow with the air in the main chamber to accelerate the combustion speed and shorten the combustion period. The thermal efficiency can be improved.

Alternatively, in this sub-chamber engine, a cavity serving as a clearance from the cylinder head lower surface is formed in the main chamber side opening of the communication hole on the piston top surface, and the communication hole is formed on the lower surface of the cylinder head. Since a guide convex portion that expands radially outward from a position corresponding to the main chamber side opening of the is formed, the jet flow ejected from the communication hole to the main chamber is generated in the main chamber by the guide convex portion. It is well diffused in a short period of time and promotes the mixing of the jet flow and fresh air to accelerate the combustion speed and shorten the combustion period to improve the thermal efficiency.

Alternatively, in this sub-chamber engine, a main chamber is formed on the cylinder side, the sub-chamber is provided substantially on the central axis of the cylinder of the cylinder head, and a communication hole that connects the main chamber and the sub-chamber is provided. Provided is a sub-chamber engine in which a plurality of sub-chambers are formed so as to be inclined toward the cylinder peripheral side, and fuel is sprayed into the sub-chamber from multiple injection holes of a fuel injection nozzle, and in particular, the communication hole is provided from the sub-chamber to the cylinder. Since the groove is formed so as to be inclined toward the peripheral side and the piston top surface is formed with a groove that extends in a radial direction around the piston from a position corresponding to the main chamber side opening of the communication hole, as described above. Similarly to the case where the branch groove is formed on the lower surface of the cylinder head, the jet flow from the communication hole further diffuses in the main chamber, promoting the mixing of the jet flow and fresh air,
It is possible to improve the air utilization rate, promote the mixing of the jet flow and the air in the main chamber, accelerate the combustion speed, shorten the combustion period, and improve the thermal efficiency.

Alternatively, in this sub-chamber engine, in particular, the communication hole is formed so as to be inclined from the sub-chamber toward the cylinder peripheral side, and the piston top surface corresponds to the main chamber side opening of the communication hole. Since the guide protrusions are formed to extend radially outward from the position, as described above, like the guide protrusions formed on the lower surface of the cylinder head, jetting from the communication hole to the main chamber is performed. The jet flow collides with the guide convex portion and is well diffused in the main chamber over the entire main chamber in a short period of time, and the jet flow and fresh air are mixed in a short period of time to accelerate the combustion speed and shorten the combustion period. Thermal efficiency can be improved.

Further, in this sub-chamber engine, the sub-chamber is located at the center of the piston head or the cylinder head, the jet flow distance from the communication hole is short, the combustion time is short, and the performance is improved. To do. Further, since the jet flow from the sub-chamber needs only to reach a short distance, the passage area of the communication hole can be made large, the squeezing loss can be reduced, and the efficiency can be improved. Further, the passage area between the main chamber and the sub chamber can be made large as a whole by the large number of the communication holes formed in the outer periphery of the sub chamber, and the squeezing loss can be reduced. Further, when the direction of inclination of the communication hole is inclined outward, the reaching distance of the jet flow from the sub chamber to the periphery of the piston is further shortened, and mixing with fresh air around the piston is promoted.

Further, in this sub-chamber engine, the combustion state in the sub-chamber can be burned in a fuel rich manner, the combustion speed equivalent to that of the direct injection type combustion chamber can be secured, and the generation of NO _X can be suppressed. Further, the flame and the air-fuel mixture formed by forming the sub chamber in the center of the cylinder from the outer circumference of the sub chamber have a shorter distance from the entire circumference of the cylinder, that is, the fresh air existing in the main chamber. Therefore, the mixing in the main chamber is promoted, the combustion speed can be increased to shorten the combustion period, and NO _x , H
It is possible to perform combustion that can suppress the generation of C and smoke.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of a sub-chamber engine according to the present invention.

FIG. 2 is a plan view showing a piston top surface of the sub-chamber engine of FIG.

3 is a graph showing the relationship between groove length and output in the subchamber engine of FIG.

FIG. 4 is an explanatory diagram showing a relationship between a groove length and a cylinder bore diameter in the sub-chamber engine of FIG.

5 is a sectional view taken along the line CC in FIG. 6 showing another embodiment of the sub-chamber engine according to the present invention.

FIG. 6 is an explanatory diagram showing a head lower surface portion of the sub-chamber engine of FIG.

FIG. 7 is a sectional view showing still another embodiment of the sub-chamber engine according to the present invention.

FIG. 8 is an explanatory diagram showing a lower surface of a head of the sub-chamber engine in FIG.

FIG. 9 is a sectional view showing another embodiment of the sub-chamber engine according to the present invention.

FIG. 10 is an explanatory view showing a head lower surface portion of the sub-chamber engine of FIG. 9.

FIG. 11 is a sectional view showing still another embodiment of the sub-chamber engine according to the present invention.

12 is an explanatory diagram showing a piston top surface of the sub-chamber engine of FIG. 11. FIG.

FIG. 13 is a sectional view showing another embodiment of the sub-chamber engine according to the present invention.

FIG. 14 is an explanatory view showing a piston top surface of the sub-chamber engine of FIG. 13.

[Explanation of symbols]

 1 Main Chamber 2 Sub Chamber 3 Cylinder 4 Communication Hole 5 Cylinder Head 6 Cylinder Block 8 Piston 9 Piston Head 10 Fuel Injection Nozzle 11 Multiple Injection Hole 12 Main Chamber Side Opening of Communication Hole 13 Intake Port 14 Head Lower Surface 15 Central Communication Hole 16 Intake valve 17 Exhaust port 22 Cavity 28 Cylinder head side groove 29 Cylinder head side branch groove 30 Piston side groove 33 Bending surface 36 Cavity 37 Piston top surface 40 Guide convex portion 41 Piston side branch groove 42 Piston side Guide protrusion

Claims (7)

[Claims] 1. A cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a sub-substitute provided on the piston substantially on the central axis of the cylinder. Room,
A plurality of communication holes that connect the main chamber and the sub chamber and are formed to incline from the sub chamber toward the cylinder peripheral side, and a central communication hole formed at the center of the upper portion of the sub chamber, and project in the vicinity of the top dead center. In a sub-chamber engine having a fuel injection nozzle having multiple injection holes for spraying fuel into the sub-chamber, a volume of the sub-chamber is set to 60% or less of a total volume at a piston top dead center, and a piston top surface is provided. Is a subchamber engine, wherein a groove extending in an outer radial direction is formed which is connected to the main chamber side opening of the communication hole. 2. The subchamber engine according to claim 1, wherein the piston peripheral portion of the groove is bent in a direction of an intake swirl remaining in the main chamber. 3. A cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a sub-substitute provided on the piston substantially on the central axis of the cylinder. Room,
A plurality of communication holes that connect the main chamber and the sub chamber and are formed to incline from the sub chamber toward the cylinder peripheral side, and a central communication hole formed at the center of the upper portion of the sub chamber, and project in the vicinity of the top dead center. In a sub-chamber engine having a fuel injection nozzle having multiple injection holes for spraying fuel into the sub-chamber, a groove that extends radially outward from a position corresponding to the main chamber side opening of the communication hole is provided on the lower surface of the cylinder head. A sub-chamber engine characterized by being formed. 4. A cylinder head attached to a cylinder block that constitutes a cylinder, a piston that reciprocates in the cylinder, a main chamber formed on the cylinder side, and a sub chamber provided on the piston substantially on the central axis of the cylinder. Room,
A plurality of communication holes that connect the main chamber and the sub chamber and are formed to incline from the sub chamber toward the cylinder peripheral side, and a central communication hole formed at the center of the upper portion of the sub chamber, and project in the vicinity of the top dead center. In a sub-chamber engine having a fuel injection nozzle having multiple injection holes for spraying fuel into the sub-chamber, a cavity serving as a clearance between a piston top surface and a main chamber-side opening of the communication hole with a lower surface of a cylinder head. The sub-chamber engine is characterized in that a groove is formed on the lower surface of the cylinder head and extends radially outward from the position corresponding to the main chamber side opening of the communication hole. 5. A cylinder head attached to a cylinder block constituting a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side, and a sub-substitute provided on the piston substantially on the central axis of the cylinder. Room,
A plurality of communication holes that connect the main chamber and the sub chamber and are formed to incline from the sub chamber toward the cylinder peripheral side, and a central communication hole formed at the center of the upper portion of the sub chamber, and project in the vicinity of the top dead center. In a sub-chamber engine having a fuel injection nozzle having multiple injection holes for spraying fuel into the sub-chamber, a cavity serving as a clearance between a piston top surface and a main chamber-side opening of the communication hole with a lower surface of a cylinder head. The auxiliary chamber engine is characterized in that a guide protrusion is formed on the lower surface of the cylinder head and extends outward in the radial direction from a position corresponding to the opening on the main chamber side of the communication hole. 6. A cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side,
A sub-chamber engine having a sub-chamber provided substantially on the central axis of the cylinder of the cylinder head, a plurality of communication holes communicating the main chamber and the sub-chamber, and a fuel injection nozzle for spraying fuel into the sub-chamber. In the above, the communication hole is formed so as to be inclined from the sub chamber toward the cylinder peripheral side, and extends on the piston top surface in a radial direction around the piston from a position corresponding to the main chamber side opening of the communication hole. A sub-chamber engine characterized by having grooves formed therein. 7. A cylinder head attached to a cylinder block forming a cylinder, a piston reciprocating in the cylinder, a main chamber formed on the cylinder side,
A sub-chamber engine having a sub-chamber provided substantially on the central axis of the cylinder of the cylinder head, a plurality of communication holes communicating the main chamber and the sub-chamber, and a fuel injection nozzle for spraying fuel into the sub-chamber. In the above, the communication hole is formed so as to be inclined from the sub-chamber toward the cylinder peripheral side, and a guide protrusion that extends radially outward from the position corresponding to the main chamber side opening of the communication hole on the piston top surface. The sub-chamber engine is characterized in that a part is formed.