JPH0777105A - Piston structure with sub-chamber - Google Patents

Abstract

(57) [Summary] [Object] The present invention improves the heat insulation of a sub-chamber formed on the piston side and reduces the heat capacity of the sub-chamber structure that constitutes the sub-chamber to improve the startability and improve the whiteness. A structure of a piston having a sub chamber for preventing smoke is provided. According to the present invention, a high-strength ceramic piston head body 1 having a cavity 4, a sub chamber 7 formed in the center of the piston formed of a thin wall body 6, and a fuel injection nozzle 23 are provided near the top dead center. A sub-chamber structure 2 made of heat-resistant ceramics, which is provided with a plurality of communication holes 5 communicating the sub chamber 7 and the main chamber 8 which are formed in the peripheral portion of the central insertion hole 22 and the sub chamber 7 which are projected, With the sub chamber structure 2 fixed to the piston head body 1, the cavity wall surface 18 and the sub chamber structure 2
And a heat shield air layer 9 which is formed over the entire area between the outer wall surface 17 and the main chamber 8 and communicates with the main chamber 8.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of a piston having a piston head with a sub chamber.

[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 a cylinder head or a piston head, a communication hole for communicating the swirl chamber with a main chamber formed on the cylinder side, and a fuel injection nozzle for spraying fuel into the swirl chamber. Then, the air-fuel mixture is formed with the fuel injected into the swirl chamber by the swirl flowing into the swirl chamber through the communication hole to perform primary combustion, and then the flame, unburned mixture gas, etc. from the swirl chamber to the main chamber through the communication hole Is ejected for secondary combustion. As an example of such a swirl chamber type engine, there is a structure of a sub-combustion chamber disclosed in JP-A-2-112613.

Further, Japanese Utility Model Publication No. 62-93141 discloses a piston having a ceramic crown and an aluminum skirt. In the piston, a ceramic crown having a cavity is fitted to a head portion of a cylindrical aluminum skirt, and a cast iron ring is made to coexist with a plastic fluid material in a gap between the outer circumference of the combustion chamber and the head portion. It is fixed.

Further, Japanese Patent Laid-Open No. 5-26111 discloses that
Adiabatic pistons are disclosed. The heat-insulating piston ensures heat insulation between the piston head and the piston skirt, prevents cracks and the like from occurring in the heat-insulating member disposed at the joint between the two, and prevents scattering of the heat-insulating member.

Further, Japanese Utility Model Laid-Open No. 60-141448 discloses a structure of a piston for an internal combustion engine having a ceramic head. The structure of the piston for an internal combustion engine is such that a metal piston body, a ceramic piston head member coaxially fitted to the top of the body, and a clearance between the side wall of the head member and the body are wedged, It is composed of a ring-shaped or segment-shaped connecting member made of a plastic fluid metal for fixing the main body and the head member to each other.

Further, Japanese Utility Model Laid-Open No. 1-113128 discloses a hot plug support structure. In the support structure for the hot plug, a recess groove is formed at an end of an inner wall surface of the recess for the sub chamber formed in the cylinder head, the recess groove being fitted with a part of the pin protruding. A groove or a concave groove into which the protruding portion of the pin is fitted is formed in the circumferential direction of the hem portion of the outer peripheral surface of the hot plug to be fitted in, and the hot plug is supported by the pin in a clearance fit state.

[0007]

To the 0005] Generally, the combustion temperature in the secondary chamber because of the high temperature, as a measure to reduce the production of NO _X, it is effective to combust the fuel-rich.
When the combustion temperature is high, it is effective to use a sub-chamber engine as a type of engine structure in order to burn the fuel rich. When the engine is configured as a sub-chamber combustion chamber, in order to increase the combustion speed of the sub-chamber combustion chamber to the same level as the combustion speed of the direct injection combustion chamber, a communication hole that connects the sub-chamber to the main chamber It is necessary to increase the cross-sectional area of the passage. However, when the passage cross-sectional area of the communication hole is increased, the ejection speed of the sub-chamber outflowing to the main chamber is reduced, and combustion in the main chamber is not sufficiently performed.

Particularly, in the sub-chamber engine, the air flow in the sub-chamber is large and the heat transfer rate is high, and the gas such as flame and unburned air-fuel mixture from the sub-chamber to the main chamber through the communication hole is high speed. Due to the jetting, the heat transfer coefficient of the communication hole becomes high. In order to improve the thermal efficiency of the engine, it is necessary to prevent heat dissipation from the sub-chamber to the outside, but to reduce heat dissipation from the sub-chamber to the outside, it is necessary to improve the heat shield of the sub-chamber. .
Further, it is important that the wall of the sub chamber is made thin to reduce the heat capacity of the sub chamber to improve the startability and prevent the generation of white smoke.

In addition, in the swirl chamber type engine, since the communication hole that connects 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 hole 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 hole 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 hole. However, there is a problem that the energy of the swirl flow cannot be fully utilized in the sub chamber.

The structure of the piston for an internal combustion engine disclosed in Japanese Utility Model Laid-Open No. 141414/1985 is a structure in which a head member and a piston body are intimately contacted with each other over the entire circumference, and an air layer is formed around them. Because it is not formed
The heat shield of the combustion chamber cannot be increased. Further, although an air layer is formed at the bottom, since the air layer and the combustion chamber do not communicate with each other, a large stress is applied to the head member due to the pressure difference between the two, and the head member is It cannot be formed thin to reduce the heat capacity. Further, the hot plug support structure disclosed in Japanese Utility Model Laid-Open No. 1-113128 uses pins for positioning, but the pins do not have a function of connecting the hot plug and the cylinder head.

Therefore, an object of the present invention is to solve the above-mentioned problems, and a sub-chamber structure for forming a sub-chamber from a piston head is constructed separately, and in particular, the piston head and the sub-chamber structure are formed. A heat-shielding air layer is formed between the sub-chambers to improve the heat-shielding degree of the sub-chambers, and the gas ejected from the sub-chambers is sped up at a high speed to improve penetration and improve the air utilization rate in the main chambers. By making the air layer around the body communicate with the combustion chamber side, the stress applied to the sub-chamber structure can be reduced, and the thickness of the sub-chamber structure can be made thin. By making the heat capacity of the sub-chamber as small as possible, the followability to the gas temperature is improved and the startability is improved, and the sub-chamber is formed in the center of the cylinder to separate the main chamber and the sub-chamber from each other. By forming multiple communication holes that communicate with each other to reduce the loss of Of the reach of the jet shortened, to promote mixing of the fresh air present in the main chamber, NO _X, carbon,
It is an object of the present invention to provide a structure of a piston having a sub chamber that reduces the generation of smoke and the like.

[0012]

In order to achieve the above object, the present invention is configured as follows. That is, the present invention relates to a piston head having a cavity, a sub chamber formed at the center of the piston formed of a thin wall, an insertion hole through which a fuel injection nozzle projects near the top dead center, and a peripheral portion of the sub chamber. A sub-chamber structure made of a heat-resistant material disposed in the cavity, the sub-chamber structure being provided in the cavity, the sub-chamber structure having a plurality of communication holes that connect the sub-chamber and the main chamber formed in the radial direction. A heat-shielding air layer which is formed in the entire region between the cavity wall surface and the outer wall surface of the sub-chamber structure except the mounting portion of the sub-chamber structure and which communicates with the main chamber. The present invention relates to the structure of a piston provided with a sub chamber.

In the structure of the piston having the sub chamber, the sub chamber structure is partially metal-flow coupled to the piston head at a plurality of positions in the circumferential direction of the cavity wall surface. Further, a heat shield material made of a low heat conductive material is incorporated in the heat shield air layer, and the heat shield air layers formed on both sides of the heat shield material communicate with the main chamber.

In the structure of the piston provided with the sub chamber, the volume of the sub chamber formed in the sub chamber structure is set to 60% or less of the total volume of the combustion chamber at the compression end. Further, the communication hole formed in the sub chamber structure,
The sub chamber extends from the sub chamber to the top surface of the piston while being inclined in the peripheral direction of the piston, and the extension line of the communication hole extends in a direction offset from the center axis of the sub chamber.

Further, in the structure of the piston provided with the sub chamber, the communication hole formed in the sub chamber structure opens into the main chamber of the tapered recess formed in the top surface of the piston head, The extension line of the communication hole extends in a direction offset from the center axis of the sub chamber.

In the structure of the piston having the sub chamber, the piston head is composed of a metal piston skirt and a high-strength ceramic piston head body fixed to the piston skirt. Further, a mounting hole is formed in the annular boss portion of the piston head body,
The sub-chamber structure is fixed to the piston head body by fitting and joining the mounting projection of the sub-chamber structure into the mounting hole. Alternatively, an annular boss portion provided on the piston head body is fitted into a mounting hole formed on the piston skirt and fixed by a coupling ring, and a heat shield air layer is provided between the piston head body and the piston skirt. And a heat shield gasket and a heat shield material are interposed.

[0017]

The present invention is constructed as described above and operates as follows. That is, the structure of the piston provided with this sub-chamber comprises a piston head having a cavity and a sub-chamber structure made of a heat-resistant material which forms the sub-chamber separately.
Since the heat-shielding air layer is formed in the entire area between the cavity wall surface and the outer wall surface of the sub-chamber structure and communicates with the main chamber, the pressure difference between the inside and the outside of the sub-chamber structure becomes almost zero. The stress applied to the sub-chamber structure is small, the thickness of the sub-chamber structure can be made thin, and the heat capacity of the sub-chamber structure can be made as small as possible. Further, since the heat shield air layer communicating with the main chamber is formed between the piston head and the sub chamber structure, the heat shield degree of the sub chamber can be significantly improved. Therefore, the heat capacity of the sub-chamber can be reduced, and the heat shield degree of the sub-chamber can be increased, so that the startability can be improved, the generation of white smoke can be prevented, and the fuel consumption can be improved. As the heat-resistant material forming the sub-chamber structure, heat-resistant ceramics such as Si ₃ N ₄ or heat-resistant alloy can be used.

Further, in the inflow and outflow of the gas into the heat shield air layer, the flow velocity of the gas is reduced, so that the thermal conductivity is lowered,
The heat shield is increased. Further, since the sub-chamber structure is partially metal-flow coupled to the cavity at a plurality of positions in the circumferential direction, the heat flow passage area between the sub-chamber and the piston head becomes small, and The heat shield can be improved.

The piston head is composed of a metal piston skirt and a high-strength ceramic piston head body fixed to the piston skirt, and a mounting hole is formed in an annular boss portion of the piston head body, and the mounting hole is formed in the mounting hole. When the mounting protrusions of the sub-chamber structure are fitted and joined together, and the sub-chamber structure is fixed to the piston head body,
Since the axial force is shared by the piston head main body, excessive stress is not applied to the combustion chamber wall surface of the sub chamber structure, and the wall thickness of the sub chamber structure can be formed as thin as possible.

Further, since the heat shield of the sub chamber can be improved, the penetration speed of gas such as flame and unburned air-fuel mixture can be increased from the sub chamber to the main chamber through the communication hole to increase the penetration. Further, since a plurality of communication holes formed in the sub chamber structure can be formed to increase the communication hole passage area as a whole, the squeezing loss can be reduced. Further, the sub chamber is located in the center of the piston, and a plurality of the communication holes are formed so as to extend in the circumferential direction, so that the distance that the jet flow from the sub chamber reaches the main chamber is shortened and the sub chamber exists in the main chamber. Mixing with fresh air is carried out in a short period of time and promoted.

[0021]

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

The structure of the piston provided with this sub-chamber includes, for example, a cylinder block 32 provided with a cylinder 31, a cylinder head 15 fixed to the cylinder block 32, a fuel injection nozzle 23 attached to the cylinder head 15 and the inside of the cylinder 31. It is applied to a subchamber engine consisting of a reciprocating piston. The structure of the piston provided with this sub-chamber forms the sub-chamber 7 on the piston side, and the volume of the sub-chamber 7 is 60% of the total volume (main chamber volume + sub-chamber volume) of the combustion chamber at the compression end.
It is applied to a sub-chamber engine configured as follows. The cylinder block 32 may have holes corresponding to the number of cylinders of the engine, and these holes may form the cylinder 31, or although not shown, the cylinder 31 is formed in the holes. The cylinder liner described above may be fitted. Although not shown, the cylinder head 15 has an intake / exhaust port, and an intake / exhaust valve is arranged in the intake / exhaust port.
In some cases, the intake / exhaust port may be provided in the lower portion of the cylinder.

The structure of the piston provided with this sub-chamber is mainly a piston skirt 3 made of a metal such as aluminum alloy or FC, and S fixed to the piston skirt 3.
It is composed of a piston head body 1 made of high strength ceramics such as i ₃ N ₄ and a sub chamber structure 2 fixed to the piston head body 1 made of heat resistant ceramics such as Si ₃ N ₄ . . In the piston skirt 3,
A piston ring groove for mounting the piston ring 27 is formed, and a mounting hole 20 is formed in the center of the upper wall body 19. The piston head main body 1 has an annular boss portion 11 at the lower center thereof and a cylindrical portion 28 extending downward at the outer peripheral portion.

The piston head body 1 and the piston skirt 3 are formed by fitting the annular boss portion 11 of the piston head body 1 into the mounting hole 20 of the piston skirt 3 and embedding the metal flow of the coupling ring 21 between them. Can be fixed to each other. At this time, a heat shield gasket 24 is interposed between the lower surface of the cylinder portion 28 of the piston head body 1 and the outer peripheral upper surface of the upper wall body 19 of the piston skirt 3 in order to seal and heat the both. Also,
The lower central surface of the piston head body 1 and the piston skirt 3
A heat shield 25 is interposed between the upper wall 19 and the central upper surface of the upper wall 19 in order to shield the heat between the two. Further, the lower surface of the piston head body 1 and the upper wall body 19 of the piston skirt 3 are
A heat-shielding air layer 26 is formed between and.

The structure of the piston provided with this sub-chamber is particularly characterized by the following constitution. At the center of the piston head body 1, a cavity 4 is formed on the top surface side and an annular boss portion 11 is formed on the bottom surface side. A mounting hole 14 is formed in the piston head body 1 at the center of the cavity 4 and at the center of the annular boss 11. The sub-chamber structure 2 is provided with a mounting projection 12 that is fitted and joined to the mounting hole 14, and the sub-chamber structure 2 is formed by fitting and mounting the mounting projection 12 into the mounting hole 14. Fixed to. Further, in the sub chamber structure 2, a sub chamber 7 is formed in the center of the piston by the thin wall body 6. The piston head body 1 and the sub-chamber structure 2 have an annular boss portion 1
1, the inner wall surface of the mounting hole 14 and the outer wall surface 13 of the mounting protrusion 12
Both are separated by a heat-shielding air layer 9 except that they are joined only in contact with. That is, in the state where the sub chamber structure 2 is fixed to the piston head body 1, the heat shield air layer 9 is formed over the entire area between the cavity wall surface 18 and the outer wall surface 17 of the sub chamber structure 2. . Further, between the cavity wall surface 18 of the piston head body 1 and the outer wall surface 17 of the sub chamber structure 2 on the top surface of the piston, the heat shielded air layer 9, the main chamber 8 and the sub chamber 7 are communicated with each other, so that the gap S Are formed.

The sub-chamber structure 2 includes the fuel injection nozzle 2
3 inserts in the vicinity of the top dead center and the insertion hole 22 in the center and the sub chamber 7
A plurality of communication holes 5 (six in FIG. 2) are formed in the peripheral portion of the container so as to connect the sub chamber 7 and the main chamber 8 formed in the radial direction.
The fuel injection nozzle 23 extends downward from the cylinder head lower surface 36 and extends from the insertion hole 22 to the sub chamber 7 near the piston top dead center.
It is set so that the fuel is injected into the sub chamber 7 through the multiple injection holes 29 provided in the fuel injection nozzle 23. Further, the sub chamber 7 formed in the sub chamber structure 2 has the cylinder 31
A communication hole 5 that is located substantially at the center of the auxiliary chamber 7 and connects the sub chamber 7 and the main chamber 8 is formed so as to be located on the outer peripheral portion of the sub chamber 7. Furthermore, the structure of the piston provided with this sub chamber is
The communication hole 5 formed in the sub chamber structure 2 opens in the main chamber 8 of the tapered recess 16 formed in the top surface of the piston head body 1, and the extension line of the communication hole 5 is slightly from the center axis of the sub chamber. It extends in an offset direction.

Since the structure of the piston provided with this sub chamber is constructed as described above, the following operation can be achieved. That is, since the structure of the piston provided with the sub chamber is configured separately from the piston head body 1 and the sub chamber structure 2, the axial force is applied to the heat shield gasket 24 so that the piston head body 1 and the piston Achieving a seal with the skirt 3 is shared by the high strength piston head body 1. Therefore, since it is not necessary for the sub-chamber structure 2 to share the application of the axial force to the heat shield gasket 24, the wall 6 forming the sub-chamber 7 of the sub-chamber structure 2 can be thinned. . The heat capacity of the thin wall body 6 forming the sub-chamber 7 in the sub-chamber structure 2 can be reduced, the followability to the gas temperature in the sub-chamber 7 becomes good, and the startability can be improved, and White smoke can be reduced.

A gap S is provided between the cavity wall surface 18 of the piston head body 1 and the outer wall surface 17 of the sub chamber structure 2.
Is formed, and since the sub chamber 7 formed in the sub chamber structure 2 and the heat shield air layer 9 are formed in communication with each other,
The pressure in the sub chamber 7 and the pressure in the heat shield air layer 9 are almost the same. Therefore, since the stress due to the pressure difference applied to the inner and outer surfaces of the sub-chamber structure 2 hardly acts on the thin wall body 6 forming the sub-chamber 7, the sub-chamber structure 2 is not damaged. . Further, since the piston head body 1 and the sub-chamber structure 2 are separated by the heat shield air layer 9, the air flow in the sub-chamber 7 is large, and the heat transfer coefficient in the sub-chamber structure 2 is high. Further, even if the high temperature gas is ejected from the communication hole 5 at a high speed and the heat transfer coefficient in the region of the communication hole 5 is increased, the heat shielding effect from the sub chamber structure 2 to the piston head body 1 is significantly improved. The heat flow from the sub chamber structure 2 to the piston head body 1 is blocked.

Further, since a plurality of communication holes 5 that connect the main chamber 8 and the sub chamber 7 are formed in the circumferential direction of the sub chamber 7, the passage area can be made large as a whole by the total of the communication holes 5, The squeezing loss can be reduced. Further, the sub chamber 7 is formed in the center of the piston, that is, in the center of the cylinder.
The arrival distance to the cylinder wall surface for the fresh air existing in the entire circumference of the cylinder 31, that is, the main chamber 8, is shortened, the air utilization rate in the main chamber 8 is improved, the mixing is promoted, and the combustion speed is increased. can shorten the combustion period, NO _X, HC, it is possible to perform the combustion that can suppress the generation of smoke. Also,
Combustion state in the auxiliary chamber 7 is burned in the fuel-rich, it is possible to suppress the generation of NO _X.

Next, another embodiment of the structure of the piston having the auxiliary chamber according to the present invention will be described with reference to FIGS. 3 and 4. This embodiment has substantially the same configuration and operation except that the structure of the communication hole is different from that of the above-mentioned embodiment, and therefore, the same reference numerals are given to the same parts and duplicate description will be given. Omit it.

In this embodiment, a plurality of communication holes 5 (six in FIG. 4) formed in the sub-chamber structure 2 extend from the sub-chamber 7 to the piston top surface 10 while being inclined in the piston peripheral direction. ing. An extension line of the communication hole 5 extends in a direction offset from the central axis of the sub chamber. The communication hole 5 provided in the sub chamber structure 2 has a tapered portion 3 extending outward in the radial direction.
It is formed to 0. Although not shown, the communication hole 5 is
It can also be formed in a pipe-shaped portion extending outward in the radial direction from the outer peripheral portion of the sub-chamber structure 2.

Next, still another embodiment of the structure of the piston having the sub chamber according to the present invention will be described with reference to FIGS. 5 and 6. FIG. 5 is a sectional view showing still another embodiment of the structure of the piston provided with the sub chamber according to the present invention, and FIG.
3 is a plan view of the piston shown in FIG. Compared with each of the above-described embodiments, this embodiment has substantially the same configuration and operation except that the sub-chamber structure is provided in the piston body, and therefore, the same parts are designated by the same reference numerals. And redundant description will be omitted.

The structure of the piston having the sub chamber of this embodiment is such that the piston main body 37 in which the piston head 39 and the piston skirt 40 are integrally formed, and the cavity 4 formed in the piston head 39 of the piston main body 37.
It is composed of the sub-chamber structure 2 arranged in. The sub-chamber structure 2 is made of heat-resistant ceramics such as Si ₃ N _4, and is inserted by inserting the sub-chamber 7 located in the center of the piston formed by a thin wall body and the fuel injection nozzle 23 near the top dead center. A plurality of communication holes 5 that are formed in the radial direction around the holes 22 and the auxiliary chamber 7 and that connect the auxiliary chamber 7 and the main chamber 8 are provided. Between the cavity wall surface 18 and the outer wall surface 17 of the sub chamber structure 2, a heat shield air layer 9 communicating with the main chamber 8 is formed over the entire area. Further, the sub-chamber structure 2 is partially plastically deformed by the bonding metal 38, that is, a metal flow, in the piston head 39 of the piston body 37 at a plurality of positions (6 positions in FIG. 6) in the circumferential direction of the cavity wall surface 18. Are combined.

As described above, the structure of the piston having the sub chamber of this embodiment is the sub chamber structure 2 and the piston head 39.
Since the metal flow coupling is performed at a plurality of points with the cavity wall surface 18 and they are coupled to each other, the heat flow passage area between the sub chamber structure 2 and the piston main body 37 forming the sub chamber 7 becomes small, The heat shield of the sub-chamber structure 2 is improved.
Further, since the heat-shielding air layer 9 on the outer periphery of the sub-chamber structure 2 and the main chamber 8 communicate with each other, the pressure difference between the sub-chamber 7 and the heat-shielding air layer 9 becomes almost zero, and the sub-chamber is formed. The structure 2 does not require strength, ie, pressure resistance against stress applied to the sub-chamber structure 2 due to the pressure difference, and the thickness of the sub-chamber structure 2 can be made as thin as possible. Therefore, the heat capacity of the sub chamber structure 2 can be reduced,
The ability of the wall surface of the sub-chamber structure 2 to follow gas is improved, the startability is improved, the weight can be reduced, and the inertial force can be reduced.

Another embodiment of the structure of the piston having a sub chamber according to the present invention will be described with reference to FIG. FIG. 7 is a sectional view showing another embodiment of the structure of the piston having the sub chamber according to the present invention. As shown in FIG. 7, in the structure of the piston having the sub chamber, the heat shield air layer 9 between the cavity wall surface 18 and the outer wall surface 17 of the sub chamber structure 2 is sealed by the seal member 41.
Can be placed to make a light seal. Seal member 4
1 can be produced, for example, by spraying zirconia or the like on the surface of the heat resistant material. By disposing the seal member 41 in the gap between the cavity wall surface 18 and the outer wall surface 17 of the sub-chamber structure 2, the flow of gas between the main chamber 8 and the heat-shielding air layer 9 can be blocked to some extent, or Can be reduced, the thermal conductivity from the sub-chamber structure 2 to the piston head 39 can be reduced, and the heat shield can be further reduced.

Still another embodiment of the structure of the piston having the sub chamber according to the present invention will be described with reference to FIG. FIG. 8 is a sectional view showing still another embodiment of the structure of the piston having the sub chamber according to the present invention. Compared with the embodiment shown in FIG. 7, this embodiment has the same structure except that a heat shield is arranged in the heat shield air layer and the sub chamber structure 2 is fixed to the piston head 39, and therefore the same parts are used. Are denoted by the same reference numerals, and redundant description will be omitted. A heat shield 25 made of a low heat conductive material is incorporated in the heat shield air layer 9. Furthermore, the heat shield 25
The heat-shielding air layers 9 formed on both sides of the chamber communicate with the main chamber 8 to eliminate the pressure difference between the inner and outer surfaces of the sub-chamber structure 2 and perform a protective function. Plays the function of up. In this embodiment, the mounting protrusion 12 of the sub chamber structure 2 is attached to the mounting hole 2 of the piston head 39.
The sub-chamber structure 2 and the piston head 39 are fixed by fitting the coupling ring 21 into the recess formed in the outer peripheral surface 13 of the mounting projection 12 by metal flow.

[0037]

The structure of the piston provided with the sub chamber according to the present invention is constructed as described above and has the following effects. The structure of the piston provided with this sub-chamber comprises a piston head and a sub-chamber structure made of a heat-resistant alloy or heat-resisting ceramics which form the sub-chamber separately, and the piston head and the sub-chamber structure are separated from each other. Since the heat-shielding air layer communicating with the combustion chamber is formed, it is not necessary to apply an axial force to the sub-chamber structure, and the wall thickness of the sub-chamber structure can be formed as thin as possible. The heat shield of the sub chamber can be greatly improved. Therefore, it is possible to reduce the heat capacity of the thin wall body that forms the sub chamber in the sub chamber structure.
The followability to the gas temperature in the sub chamber is improved, the startability can be improved, and white smoke can be reduced. In addition, the high-temperature gas in the sub chamber can be ejected from the sub chamber through the communication hole into the main chamber at a high speed to eject gas such as flame and unburned air-fuel mixture, thereby increasing the penetration in the main chamber.

In particular, the structure of the piston having this sub chamber is
For fixing the piston head and the sub chamber structure,
Since the metal flow is partially performed around the sub-chamber structure with the combined metal, the area of the heat flow passage between the sub-chamber and the piston head is reduced, and the heat shielding property of the sub-chamber can be improved. Since the heat-shielding air layer formed around the sub-chamber structure and the main chamber are in communication with each other, the pressure difference between the sub-chamber and the heat-shielding air layer becomes almost zero,
The strength of the sub-chamber structure against the pressure difference, that is, the pressure resistance becomes unnecessary, the sub-chamber structure can be formed thin, the heat capacity of the sub-chamber structure can be reduced, and a low compression ratio can be achieved.
The starting property can be improved, the sub-chamber structure itself can be configured to be lightweight, the inertial force with respect to the reciprocating motion of the piston can be reduced, and the coupling force between the piston head and the sub-chamber structure is sufficient even with a partial metal flow. become. Further, when a sealing member is arranged between the piston head and the sub chamber structure to perform light sealing, gas inflow and outflow between the main chamber and the heat shield air layer is reduced. The gas flow velocity is reduced, the heat transfer coefficient from the sub chamber to the piston head can be reduced, and the heat shield property of the sub chamber is improved.

In the structure of the piston provided with this sub-chamber, the high-strength ceramic piston head main body attached to the piston skirt and the heat-resistant ceramic sub-chamber structure forming the sub-chamber are constructed separately, Since the axial force for sealing, which is interposed between the piston skirt and the piston head main body, is shared by the piston head main body, it is not necessary to apply an axial force to the sub chamber structure, and the sub chamber structure is not required. The wall thickness of the body can be made as thin as possible.

Further, a gap is formed between the cavity wall surface of the piston head body and the outer wall surface of the sub chamber structure so as to communicate with the main chamber, and the sub chamber formed by the sub chamber structure. It is formed in a state of communicating with the heat-shielding air layer, the pressure in the sub-chamber and the pressure in the heat-shielding air layer are substantially the same, and the thin wall body forming the sub-chamber has a pressure. Since the stress due to the difference hardly acts, the sub-chamber structure is not damaged. Further, the piston head body and the sub chamber structure are separated by the heat shield air layer, and the heat shielding effect from the sub chamber structure to the piston head body is significantly improved. Even if the air flow in the sub chamber structure is large and the high temperature gas is ejected from the communication hole at a high speed to increase the heat transfer coefficient of the sub chamber structure and the communication hole, the piston head body is ejected from the sub chamber structure. The heat flow to is blocked.

Further, since a plurality of the communication holes that communicate the main chamber and the sub chamber are formed in the circumferential direction of the sub chamber, the passage area can be made large in total as a whole of the communication holes. The squeezing loss can be reduced. Further, the sub chamber is formed in the center of the piston, that is, in the center of the cylinder, and gases such as flame and unburned air-fuel mixture ejected from the outer periphery of the sub chamber to the main chamber through the communication hole are fresh air existing in the main chamber. On the other hand, the reaching distance to the cylinder wall surface is shortened, the air utilization ratio in the main chamber is improved to promote mixing, the combustion speed is increased to shorten the combustion period, and NO _x , HC, and smoke are generated. It is possible to perform combustion capable of suppressing the above. Further, the combustion state in the sub chamber is burned in a fuel rich state,
The occurrence of O _X can be suppressed.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of the structure of a piston having a sub chamber according to the present invention.

FIG. 2 is a plan view of the piston shown in FIG.

FIG. 3 is a sectional view showing another embodiment of the structure of a piston having a sub chamber according to the present invention.

FIG. 4 is a plan view of the piston shown in FIG.

FIG. 5 is a sectional view showing still another embodiment of the structure of the piston having the sub chamber according to the present invention.

FIG. 6 is a plan view of the piston shown in FIG.

FIG. 7 is a sectional view showing another embodiment of the structure of the piston provided with the sub chamber according to the present invention.

FIG. 8 is a sectional view showing still another embodiment of the structure of the piston having the sub chamber according to the present invention.

[Explanation of symbols]

 1 Piston Head Main Body 2 Sub Chamber Structure 3 Piston Skirt 4 Cavity 5 Communication Hole 7 Sub Chamber 8 Main Chamber 9,26 Heat Shielding Air Layer 10 Top Surface 11 Annular Boss 12 Mounting Projection 14 Mounting Hole 16 Recess 17 Outer Wall Surface 18 Cavity wall surface 20 Mounting hole 21 Coupling ring 22 Insertion hole 23 Fuel injection nozzle 24 Heat shield gasket 25 Heat shield material 37 Piston body 38 Coupling metal 39 Piston head 40 Piston skirt 41 Seal member

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display area F02F 3/00 301 Z Z 302 A

Claims (9)

[Claims] 1. A piston head having a cavity, a sub chamber formed at the center of the piston formed of a thin wall, an insertion hole into which a fuel injection nozzle projects near the top dead center, and a peripheral portion of the sub chamber. A sub-chamber structure made of a heat-resistant material disposed in the cavity provided with a plurality of communication holes communicating the sub-chamber and the main chamber formed in the radial direction, and the sub-chamber structure on the piston head. And a heat-shielding air layer which is formed in the entire area between the cavity wall surface and the outer wall surface of the sub-chamber structure except the mounting portion of the sub-chamber structure in a fixed state and communicates with the main chamber. Structure of the piston with a sub chamber characterized by. 2. The sub chamber according to claim 1, wherein the sub chamber structure is partially metal-flow coupled to the piston head at a plurality of circumferential positions of the cavity wall surface. Piston structure. 3. A heat shield material made of a low heat conductive material is incorporated in the heat shield air layer, and the heat shield air layers formed on both sides of the heat shield material communicate with the main chamber. The structure of the piston provided with the subchamber according to claim 1 or 2. 4. The volume of the sub-chamber formed in the sub-chamber structure is set to 60% or less of the total volume of the combustion chamber at the compression end. The structure of the piston provided with the sub chamber described in Crab. 5. The communication hole formed in the sub-chamber structure extends from the sub-chamber to the top surface of the piston while being inclined in the peripheral direction of the piston, and the extension line of the communication hole is offset from the central axis of the sub-chamber. The structure of the piston provided with the sub chamber according to any one of claims 1 to 4, which extends in the direction. 6. The connecting hole formed in the sub-chamber structure opens in a main chamber of a tapered recess formed in the top surface of the piston head, and an extension line of the connecting hole extends from a central axis of the sub-chamber. The structure of a piston provided with a sub chamber according to any one of claims 1 to 5, which extends in an offset direction. 7. The sub chamber according to claim 1, wherein the piston head comprises a metal piston skirt and a high-strength ceramic piston head main body fixed to the piston skirt. Structure of the piston with. 8. A mounting hole is formed in an annular boss portion of the piston head main body, and a mounting projection of the sub chamber structure is fitted and joined to the mounting hole to connect the sub chamber structure to the piston head. The structure of a piston having a sub chamber according to claim 7, which is fixed to a main body. 9. An annular boss portion provided on the piston head body is fitted into a mounting hole formed on the piston skirt and fixed by a coupling ring, and a shield is provided between the piston head body and the piston skirt. 9. The structure of a piston having a sub chamber according to claim 7, wherein a hot air layer is formed and a heat insulating gasket and a heat insulating material are interposed.