JP2016075207A - Combustion chamber structure of direct-injection type engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a combustion chamber structure of a direct-injection type engine capable of reducing generation of smoke, CO and the like in comparison with a conventional one.SOLUTION: In a combustion chamber structure 1 of a direct-injection type engine including a curve portion 6 having a longitudinal cross-sectional shape defined by a circular arc curve projecting to a radial outer side of a piston 1, a bottom wall straight portion 9 having a longitudinal cross-sectional shape defined by a straight line, and a bottom wall relaxation curve portion 8 having a longitudinal cross-sectional shape defined by a relaxation curve of which a radius of curvature is continuously changed from a radius of curvature of the circular arc curve defining the longitudinal cross-sectional shape of the curve portion 6 to infinity, at least a wall surface of the bottom wall straight portion 8 is coated with a material 11 capable of adsorbing a substance having electric charge repulsing electric charge of fuel spray F.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a combustion chamber structure of a direct injection engine, and more particularly to a combustion chamber structure of a direct injection engine that can reduce the generation of smoke, CO, and the like as compared with the conventional one.

  Generally, the combustion chamber structure of a direct injection type engine includes a reentrant type cavity recessed in the center of the top of a piston. In such a combustion chamber structure, most of the fuel (hereinafter referred to as “fuel spray”) injected from the injector toward the inner side wall of the cavity when the piston reaches near the compression top dead center. Although it flows downward along the wall surface, the speed decreases at a discontinuous portion between the curved portion and the bottom wall straight portion. If the flow rate of the fuel spray is reduced, the fuel concentration is increased and mixing with air is prevented, so that smoke, carbon monoxide (CO), and the like are generated during combustion.

  In order to solve such a problem, it has a longitudinal cross-sectional shape defined by a relaxation curve between the curved part of the cavity and the straight part of the bottom wall so that the flow of the fuel spray does not stay in the cavity. A combustion chamber structure provided with a bottom wall relaxation curve portion has been proposed (see Patent Document 1).

  As a result of the inventor's extensive research on the combustion chamber structure according to Patent Document 1, the factor that hinders the mixing of fuel spray and air is that the velocity energy of the fuel spray is attenuated by friction with the wall of the cavity. As a result of finding out that there is also a decrease in the flow of fuel spray due to this, the present invention has been completed.

JP 2013-217306 A

  An object of the present invention is to provide a combustion chamber structure of a direct injection engine that can reduce the generation of smoke, CO, and the like as compared with the conventional art.

  A combustion chamber structure of a direct injection engine of the present invention that achieves the above object comprises a cavity that is recessed in the center of the top surface of the piston and injects fuel from an injector disposed above the piston, A curved portion having a longitudinal sectional shape defined by an arc curve protruding outward in the radial direction of the piston, and a bottom wall straight portion provided on a bottom wall of the cavity having a longitudinal sectional shape defined by a straight line And the curved portion in the bottom wall of the cavity having a longitudinal cross-sectional shape defined by a relaxation curve whose curvature radius continuously changes from the radius of curvature of the circular arc curve defining the longitudinal sectional shape of the curved portion to infinity, and A combustion chamber structure of a direct injection engine including a bottom wall relaxation curve portion provided between the bottom wall straight portion and at least a wall surface of the bottom wall straight portion, A material capable of adsorbing a substance having an electric charge repelled from the injected fuel, or a material containing a metal containing an atom belonging to any one of Group 1, Group 2 or Group 14-17 of the periodic table It is characterized by being coated with.

  According to the combustion chamber structure of the direct injection engine of the present invention, the friction between the fuel spray and the wall surface is reduced in the straight line of the bottom wall occupying a large area of the cavity, and the moving speed of the fuel spray does not decrease. Since mixing of fuel spray and air is promoted, smoke, CO, and the like can be reduced as compared with the prior art.

1 is a half sectional view of a piston showing a configuration of a combustion chamber structure of a direct injection engine according to an embodiment of the present invention.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a combustion chamber structure of a direct injection engine according to an embodiment of the present invention.

  The combustion chamber structure 1 of the direct injection engine (hereinafter simply referred to as “combustion chamber structure”) has the same basic structure as the invention disclosed in Patent Document 1, A cavity 2 is provided in the center of the top of the piston 1 so as to be recessed. The shape of the cavity 2 is preferably exemplified by a reentrant type, but is not limited thereto, and may be a toroidal type or a lip type, for example.

  A side wall straight part 4, a side wall relaxation curve part 5, and a curved part (depression part) 13 are successively provided in the lower part of the side wall 3 inside the cavity 2.

  The side wall relaxation curve portion 5 has a radius of curvature that protrudes outward in the radial direction that defines the vertical cross-sectional shape of the curved portion 6 from the curvature radius (infinite) of the straight line that defines the vertical cross-sectional shape of the side wall straight portion 4. It has a longitudinal cross-sectional shape defined by a relaxation curve that continuously changes to the radius of curvature (constant) of the arc curve. That is, the radius of curvature of the relaxation curve that defines the longitudinal cross-sectional shape of the sidewall relaxation curve portion 5 gradually decreases from the side wall straight portion 4 side toward the curve portion 6 side within the curve section.

  The bottom wall 7 of the cavity 2 is provided with a bottom wall relaxation curve portion 8 and a bottom wall straight line portion 9 successively in order from the curve portion 6 toward a frustoconical ridge 10 formed radially inward. It has been.

  The bottom wall relaxation curve portion 8 defines the vertical cross-sectional shape of the bottom wall straight line portion 9 from the radius of curvature (constant) of the arc curve that protrudes radially outward that defines the vertical cross-sectional shape of the curved portion 6. It has a longitudinal cross-sectional shape defined by a relaxation curve that continuously changes to the radius of curvature (infinite) of the straight line. That is, the radius of curvature of the relaxation curve that defines the longitudinal cross-sectional shape of the bottom wall relaxation curve portion 8 gradually increases from the curve portion 6 side to the bottom wall straight portion 9 side within the curve section.

  As a relaxation curve which prescribes | regulates the longitudinal cross-sectional shape of said side wall relaxation curve part 5 and bottom wall relaxation curve part 8, a clothoid curve is illustrated preferably, However, it is not limited to this, A cubic parabola (cubic curve) Alternatively, it may be a sine curve (sine half wavelength decreasing curve).

  A fuel F (hereinafter referred to as “fuel spray F”) injected from an injector (not shown) disposed above the piston 1 toward the side wall 3 inside the cavity 2 described above is a side wall straight portion 4. And from the side wall relaxation curve part 5 to the bottom wall relaxation curve part 8 and the bottom wall straight line part 9 through the curve part 6, it mixes with air, flowing continuously without stopping along the wall surface.

  The wall 11 of the bottom wall straight portion 9 in the cavity 2 of the combustion chamber structure 1 is coated with a material 11 that can adsorb a substance having a charge repelling the charge of the fuel spray F.

  The fuel spray F flowing in the cavity 2 has a positive or negative charge depending on its molecular state. Specifically, the charge of the fuel spray F is more likely to be negative when the charge train of the material of the fuel ejection holes is positive, and more likely to be positive when the charge train is negative. Therefore, a substance having a charge repelling the charge of the fuel spray F becomes a negatively charged substance when the charge of the fuel spray F is negative, while it becomes a positively charged substance when it is positive.

  As the material 11 capable of adsorbing a negatively charged substance, glass is exemplified. Further, as the material 11 capable of adsorbing a positively charged substance, Teflon (registered trademark of DuPont) is exemplified.

  The method of coating the material 11 on the wall surface of the bottom wall straight line portion 9 is not particularly limited, and examples thereof include vapor deposition, sintering, immersion, thermal spraying, and plasma CVD.

  By performing such surface processing, in the bottom wall straight portion 9 occupying a large area of the cavity 2, the friction between the two becomes low due to the electric repulsive force generated between the fuel spray F and the wall surface. Since the moving speed of the spray F does not decrease, mixing of the fuel spray F and air is promoted, so that smoke, CO, and the like can be reduced as compared with the prior art.

  In another embodiment of the present invention, at least the wall surface of the bottom wall straight portion 9 in the cavity 2 of the combustion chamber structure 1 is in any one of the first group, the second group, or the fourteenth to seventeenth group of the periodic table. A material 12 made of a metal containing the atoms to which it belongs is coated. In addition, you may make it use the material 12 which contains the atom which belongs to either the 1st group of the periodic table, a 2nd group, or the 14th-17th group in the surface crystal structure.

  A method for coating the material 12 on the wall surface of the bottom wall straight portion 9 is not particularly limited, and examples thereof include vapor deposition, sintering, immersion, thermal spraying, and plasma CVD.

  Even by performing the surface processing to coat the material 12 as described above, the friction between the two due to the electric repulsive force generated between the fuel spray F and the wall surface in the bottom wall straight portion 9 occupying a large area of the cavity 2. Can be lowered.

  In the two embodiments described above, the materials 11 and 12 described above can be coated on portions other than the bottom wall straight portion 9, for example, the curved portion 6 and the bottom wall relaxation curved portion 8.

  The direct injection engine in the present invention is not limited to a direct injection diesel engine, and may be a direct injection gasoline engine.

DESCRIPTION OF SYMBOLS 1 Piston 2 Cavity 3 Side wall 4 Side wall straight part 5 Side wall relaxation curve part 6 Curve part 7 Bottom wall 8 Bottom wall relaxation curve part 9 Bottom wall straight part 10 Raised part 11, 12 Material F Fuel spray

Claims (3)

A cavity is provided in the central portion of the top surface of the piston, and fuel is injected from an injector disposed above the piston, and the cavity is defined by an arc curve projecting radially outward of the piston. A curved portion having a longitudinal sectional shape, a bottom wall straight portion provided on the bottom wall of the cavity having a longitudinal sectional shape defined by a straight line, and an arc curve whose curvature radius defines the longitudinal sectional shape of the curved portion. A bottom wall relaxation provided between the curved portion and the bottom wall straight portion of the bottom wall of the cavity having a longitudinal cross-sectional shape defined by a relaxation curve continuously changing from a radius of curvature to infinity. In a combustion chamber structure of a direct injection engine including a curved portion,
A material capable of adsorbing a substance having a charge repelling the charge of the injected fuel at least on the wall surface of the bottom wall straight line portion, or any one of Group 1, Group 2 or Groups 14-17 of the periodic table A combustion chamber structure for a direct-injection engine, which is coated with a material containing a metal containing atoms belonging to   In the case where at least the wall surface of the straight portion of the bottom wall is coated with a material capable of adsorbing a substance having a charge repelling the charge of the injected fuel, the material being glass or Teflon (registered trademark of DuPont) The combustion chamber structure of a direct injection type engine according to claim 1.   The cavity is provided at an upper portion of the side wall of the cavity, and is provided at a side wall straight portion having a vertical cross-sectional shape defined by a straight line, and is provided on the side wall of the cavity between the side wall straight portion and the curved portion. And a sidewall relaxation curve portion having a longitudinal sectional shape defined by a relaxation curve that continuously changes from an infinite curvature radius to a curvature radius of an arc curve that defines the longitudinal sectional shape of the curved portion. Or the combustion chamber structure of the direct injection type engine of 2.

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