KR101217044B1 - Cylinder Head Gasket Having the Structure of Double Stopper - Google Patents

Abstract

A cylinder head gasket comprising: an upper bead plate for forming a concave full bead along a bore side rim so as to apply a gromm stopper structure inside the combustion chamber to increase surface pressure to increase sealing; A lower bead plate having a same shape symmetrical with the upper bead plate and having a convex pull bead formed along a bore side edge corresponding to the concave pull bead; A grommet plate interposed between the upper bead plate and the lower bead plate, the flat plate forming a fold portion having one side end folded at a constant width along a bore edge; And the shim stopper plate positioned in the folding direction of the grommet plate so as to contact and engage with the grommet plate between the full beads of the upper and lower bead plates. Relates to a gasket.

Description

Cylinder Head Gasket Having the Structure of Double Stopper

The present invention relates to a cylinder head gasket having a double stopper structure, and more particularly, to a double stopper structure in which a bead and a stopper structure are doubled for sealing a fluid gap generated between a cylinder block and a cylinder head of an internal combustion engine. Relates to a cylinder head gasket.

In general, a gasket is a means for preventing leakage by being sandwiched between parts and mating surfaces or contact surfaces between parts.

For example, a special structure is applied to a cylinder of an internal combustion engine (engine) in order to prevent leakage of high pressure combustion gas in a combustion chamber inside a cylinder in a gasket provided between a cylinder block and a deck face of a cylinder head.

This is due to the high force generated between the cylinder block and the cylinder head due to the high pressure generated in the process of compression, expansion, explosion, exhaust, etc. inside the cylinder, so that a minute gap temporarily flows between the cylinder block and the cylinder head. Because of this, a structure for sealing this gap is required.

In general, such a fine gap in a compression ignition engine is known to be about 10 μm (= 0.01 mm) to 15 μm (= 0.015 mm).

If the high pressure combustion gas leaks through the minute gap, the combustion efficiency of the internal combustion engine is deteriorated, which should be prevented.

Therefore, there have been a lot of proposals for sealing minute gaps occurring in cylinders of internal combustion engines.

Figure 1 of the accompanying drawings is a schematic diagram showing the structure of a gasket for a conventional cylinder sealing.

As shown in FIG. 1, generally, the gasket 10 is a metal sheet and has a single layer or a multilayer structure. Each metal sheet includes a bore corresponding to a cylinder hole and a supply hole such as lubricating oil and cooling water, Rivets, bolt assembly holes, and the like are formed.

In addition, the bore side of the metal sheet is provided with a bore side structure as a special structure for sealing the minute gap generated in the fluid.

As a structure for such a bore side sealing, a shim stopper type or a grommet stopper type has been proposed.

As shown in FIG. 1, the shim-stopper structure applies a stopper plate 1 having a constant thickness to the bore portion pole in a manner of maintaining the sealing while minimizing the bore deformation.

In addition, as shown in Figure 2, the grommet structure is a method of maintaining the sealing through the overlapping the soft material (2).

The shim-stopper structure has the same thickness on the periphery of the bore part, and the surface pressure distribution by the stopper is uniform during fastening, but the surface pressure is generated over a large area so that high surface pressure is hardly generated, thus increasing the engine combustion pressure. As a result, there is a limit to supplementing or securing gas sealing properties.

In addition, the grommet-stopper structure is a sealing structure using the difference in the thickness of the material, when the high surface pressure is generated in the grommet portion when tightening, but a high surface pressure is generated in the local area may cause problems such as head, block deformation.

Accordingly, an object of the present invention for solving the above problems is to provide a cylinder head gasket having a double stopper structure by combining a grommet stopper structure with a seam stopper structure to present a structure having the advantages of two structures.

SUMMARY OF THE INVENTION An object of the present invention is a cylinder head gasket, comprising: an upper bead plate forming concave full beads along a bore side edge; A lower bead plate having a same shape symmetrical with the upper bead plate and having a convex pull bead formed along a bore side edge corresponding to the concave pull bead; A grommet plate interposed between the upper bead plate and the lower bead plate, the flat plate forming a fold portion having one side end folded at a constant width along a bore edge; And the shim stopper plate positioned in the folding direction of the grommet plate so as to contact and engage with the grommet plate between the full beads of the upper and lower bead plates. Achieved by a gasket.

In addition, according to the present invention, the upper bead plate, the flat surface horizontal from the bore side; A full bead concave from the bore-side flat surface; A full bead-side flat surface extending from the full bead and having the same height as the bore-side flat surface; An inclined surface inclined downward from the full bead side flat surface; It is preferable that it is comprised from the inclined surface side flat surface horizontal from the said inclined surface.

In addition, according to the present invention, the lower bead plate, the flat surface horizontal from the bore side; A full bead convex from the bore-side flat surface; A full bead-side flat surface extending from the full bead and having the same height as the bore-side flat surface; An inclined surface inclined upwardly from the full bead-side flat surface; It is preferable that it is comprised from the inclined surface side flat surface horizontal from the said inclined surface.

In addition, according to the present invention, the shim stopper plate is formed of a flat plate having a thickness less than the thickness of the grommet plate, so that the thickness of the range where the folded portion of the grommet plate is located is the interview between the shim stopper plate and the grommet plate It is preferred to be thicker than the thickness of the range.

In addition, according to the present invention, the grommet plate is folded in the direction of the lower bead plate, it is preferable that the shim stopper plate is positioned to interview the lower surface of the grommet plate.

Further, according to the present invention, the other side end of the grommet plate is engaged with the inclined surface side flat surface of the bead plate, the other side end of the shim stopper plate is preferably located between the bead side flat surface.

Further, according to the present invention, the other side end of the grommet plate is engaged with the full bead side flat surface of the bead plate, and the other side end of the shim stopper plate is preferably located between the inclined surface side flat surface.

In addition, according to the present invention, the grommet plate is folded in the direction of the upper bead plate, it is preferable that the shim stopper plate is positioned to interview the upper surface of the grommet plate.

Further, according to the present invention, the other side end of the grommet plate is engaged with the inclined surface side flat surface of the bead plate, the other side end of the shim stopper plate is preferably located between the bead side flat surface.

Further, according to the present invention, the other side end of the grommet plate is engaged with the full bead side flat surface of the bead plate, and the other side end of the shim stopper plate is preferably located between the inclined surface side flat surface.

Therefore, the cylinder head gasket having the double stopper structure of the present invention by the above-mentioned problem solving means increases the surface pressure by applying the grommet stopper structure to the inside of the combustion chamber, and increases the sealing property, and the seam stopper structure is applied to the other parts in a large area. By causing the surface pressure to be generated, it is possible to suppress the vibration and amplitude of the bore mold and the head, thereby removing the durability anxiety factor.

1 is a side cross-sectional view of a cylinder head gasket having a conventional shim-stopper structure.
2 is a side cross-sectional view of a cylinder head gasket having a conventional grommet-stopper structure.
3 is a side cross-sectional view of a cylinder head gasket having a double stopper structure according to the first embodiment of the present invention;
4 is a side cross-sectional view of a cylinder head gasket having a double stopper structure according to a second embodiment of the present invention;
5 is a side cross-sectional view of a cylinder head gasket having a double stopper structure according to a third embodiment of the present invention;
6 is a side cross-sectional view of a cylinder head gasket having a double stopper structure according to a fourth embodiment of the present invention.

Hereinafter, a cylinder head gasket having a double stopper structure according to embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

As shown in FIG. 3, the cylinder head gasket having the double stopper structure according to the first embodiment of the present invention includes a grommet plate 30 and a shim stopper interposed between the upper and lower bead plates 10 and 20 and the bead plate. It consists of a plate 40.

That is, the present invention consists of two upper and lower metal plates, and sandwiches a shim stopper plate and a grommet plate between the upper and lower metal plates.

Hereinafter, since the upper and lower metal plates of the embodiments described in FIGS. 4 to 6 are the same as or similar to those of the upper and lower metal plates described in the first embodiment, detailed descriptions thereof will be omitted.

The bead plates form a concave or convex full bead, wherein the full bead is a structure in which a portion of the thin metal plate is curved, and has a structure that is compressed-restored by a constant elastic force during load compression and release.

In addition, the bead plates form an inclined half bead having a downward slope along the edge.

More specifically, the upper bead plate 10 has a flat surface 11 horizontal from the bore side, a full bead 12 concave from the flat surface 11, and a flat surface having the same height as the flat surface 11. It consists of the surface 13, the inclined surface 14 inclined downward from the flat surface 13, and the flat surface 15 horizontal from the inclined surface 14.

Similarly, the lower bead plate 20 has a flat surface 21 horizontal from the bore side, a full bead 22 convex from the flat surface 21, and a flat surface having the same height as the flat surface 21 ( 23, the inclined surface 24 inclined upward from the flat surface 23, and the flat surface 25 horizontal from the inclined surface 24.

The grommet plate 30 is a flat plate whose one end is located on the same line as the one end of the upper and lower bead plates, and the other end is positioned between the flat surfaces 13 and 23 of the upper and lower bead plates.

At this time, one side end of the grommet plate 30 forms a folded portion 31 that is folded downward while maintaining a constant width along the bore portion edge.

The shim stopper plate 40 is a flat plate having a thickness smaller than the thickness of the grommet plate 30 and is characterized in that it is interviewed with the grommet plate 30 in the lower portion of the grommet plate 30.

One end of the shim stopper plate 40 is located between the bore edge of the upper and lower bead plates and the beads, and the other end is interposed between the flat surfaces 15 and 25 of the upper and lower bead plates.

Therefore, the shim stopper plate 40 is interposed so that one side of the shim stopper plate is interviewed with the lower surface of the grommet plate 30, and the upper and lower beads are positioned to engage each other.

Only R1 which is a range where the folded portion 31 of the grommet plate 30 is located, R2 which is a range where the shim stopper plate 40 and the grommet plate 30 are interviewed, and the shim stopper plate 40 are positioned In the range R3, since the grommet plate 30 is formed thicker than the thickness of the shim stopper plate 40, the thickness of R1 is thicker than the thickness of R2.

Therefore, as the thickness of each section is changed, the surface pressure level of each gasket portion is changed to increase the surface pressure of the bore portion, thereby making the sealing more solid.

As shown in FIG. 4, the cylinder head gasket having the double stopper structure according to the second embodiment of the present invention includes a grommet plate 130 and a shim stopper interposed between the upper and lower bead plates 110 and 120 and the bead plate. It is composed of a plate (140).

The upper bead plate 110 has a bore-side flat surface 111 horizontal from the bore side, a pool bead 112 concave from the bore-side flat surface 111, and a pool having the same height as the flat surface 111. The bead side flat surface 113, the inclined surface 114 inclined downward from the full bead side flat surface 113, and the inclined surface side flat surface 115 horizontal from the inclined surface 114 are comprised.

Similarly, the lower bead plate 120 has the same height as that of the bore-side flat surface 121 which is horizontal from the bore side, the full bead 122 and the flat surface 121 which are convex from the bore-side flat surface 121. The full bead side flat surface 123 of, the inclined surface 124 inclined upward from the full bead side flat surface 123, and the inclined surface side flat surface 125 horizontal from the inclined surface 124.

The grommet plate 130 is a flat plate whose one end is positioned on the same line as the one end of the upper and lower bead plates, and the other end is positioned between the flat surfaces 113 and 123 of the upper and lower bead plates.

At this time, one side end of the grommet plate 130 forms a folded portion 131 which is folded upward while maintaining a constant width along the bore portion edge.

The shim stopper plate 140 is a flat plate having a thickness smaller than the thickness of the grommet plate 130, and the seam stopper plate 140 is interviewed with the grommet plate 130 at an upper surface of the grommet plate 130.

One end of the shim stopper plate 140 is positioned between the bore edge of the upper / lower bead plate and the bead, and the other end is interposed between the flat surfaces 115 and 125 of the upper and lower bead plates.

Therefore, the shim stopper plate 140 is interposed so that one side of the shim stopper plate is interviewed with the upper surface of the grommet plate 130, and the upper and lower beads are positioned to engage with each other.

R1 which is a range where the folded portion 131 of the grommet plate 130 is located, R2 which is a range where the shim stopper plate 140 and the grommet plate 130 are interviewed, and only the shim stopper plate 140 are positioned. In the range R3, since the grommet plate 130 is formed thicker than the thickness of the shim stopper plate 140, the thickness of R1 is thicker than the thickness of R2.

As shown in FIG. 5, a cylinder head gasket having a double stopper structure according to a third embodiment of the present invention includes a grommet plate 230 and a shim stopper interposed between upper and lower bead plates 210 and 220 and the bead plate. It consists of a plate 240.

The upper bead plate 210 has a flat surface 211 horizontal from the bore side, a full bead 212 concave from the flat surface 211, and a flat surface 213 having the same height as the flat surface 211. And an inclined surface 214 inclined downward from the flat surface 213 and a flat surface 215 horizontal from the inclined surface 214.

Similarly, the lower bead plate 220 has a flat surface 221 horizontal from the bore side, a full bead 222 convex from the flat surface 221, and a flat surface having the same height as the flat surface 221 ( 223, an inclined surface 224 inclined upward from the flat surface 223, and a flat surface 225 horizontal from the inclined surface 224.

The grommet plate 230 is a flat plate whose one end is positioned on the same line as the one end of the bore side upper and lower bead plates, and the other side is positioned between the flat surfaces 215 and 225 of the upper and lower bead plates.

At this time, one side end of the grommet plate 230 forms a folded portion 231 that is folded down while maintaining a constant width along the bore edge.

The shim stopper plate 240 is a flat plate having a thickness smaller than the thickness of the grommet plate 230 and is characterized in that the lower portion of the grommet plate 230 and an interview with the grommet plate 230.

One end of the shim stopper plate 240 is positioned between the bore edge of the upper and lower bead plates and the beads, and the other end is interposed between the flat surfaces 213 and 223 of the upper and lower bead plates.

Therefore, the shim stopper plate 240 is interposed so that one side of the shim stopper plate 240 is interviewed with the lower surface of the grommet plate 230, and the upper and lower beads are positioned to engage each other.

R1 which is a range where the folded portion 231 of the grommet plate 230 is located, R2 which is a range where the shim stopper plate 240 and the grommet plate 230 are interviewed, and only the shim stopper plate 240 are positioned. In the range R3, since the grommet plate 230 is formed thicker than the thickness of the shim stopper plate 240, the thickness of R1 becomes thicker than the thickness of R2.

As shown in FIG. 6, the cylinder head gasket having the double stopper structure of the present invention includes a grommet plate 330 and a shim stopper plate 340 interposed between the upper and lower bead plates 310 and 320 and the bead plate. do.

The upper bead plate 310 has a flat surface 311 horizontal from the bore side, a full bead 312 concave from the flat surface 311, and a flat surface 313 having the same height as the flat surface 311. And an inclined surface 314 inclined downward from the flat surface 313 and a flat surface 315 horizontal from the inclined surface 314.

Similarly, the lower bead plate 320 has a flat surface 321 horizontal from the bore side, a full bead 322 convex from the flat surface 321, and a flat surface having the same height as the flat surface 321 ( 323, an inclined surface 324 inclined upward from the flat surface 323, and a flat surface 325 horizontal from the inclined surface 324.

The grommet plate 330 is one side end is located on the same line as the one side end of the upper and lower bead plate, the other end is a flat plate interposed between the flat surface (315, 325) of the upper and lower bead plate.

At this time, one side end of the grommet plate 330 forms a folded portion 331 which is folded upward while maintaining a constant width along the bore portion edge.

The shim stopper plate 340 is a flat plate having a thickness smaller than the thickness of the grommet plate 330 and is characterized in that the upper surface of the grommet plate 330 is interviewed with the grommet plate 330.

One end of the shim stopper plate 340 is positioned between the bore edge of the upper and lower bead plates and the beads, and the other end is positioned between the flat surfaces 313 and 323 of the upper and lower bead plates.

Therefore, the shim stopper plate 340 is interposed so that one side of the shim stopper plate 330 is interviewed on the upper surface of the grommet plate 330, and the upper and lower beads are positioned to engage each other.

Only R1 which is a range where the folded portion 331 of the grommet plate 330 is located, R2 which is a range where the shim stopper plate 340 and the grommet plate 330 are interviewed, and the shim stopper plate 340 are positioned only In the range R3, since the grommet plate 330 is formed thicker than the thickness of the shim stopper plate 340, the thickness of R1 is thicker than the thickness of R2.

10, 110, 210, 301: upper bead plave
11, 13, 15: flat surface
12, 22: full bead 14, 24: slope
20, 120, 220, 320: lower bead plate
21, 23, 25: flat surface
30, 130, 230, 330: Grommet Plate
31: folded
40. 140, 240, 340: seam stopper plate

Claims (10)

In the cylinder head gasket,
An upper bead plate forming a concave full bead along the bore side edge;
A lower bead plate having a same shape symmetrical with the upper bead plate and having a convex pull bead formed along a bore side edge corresponding to the concave pull bead;
A grommet plate interposed between the upper bead plate and the lower bead plate, the flat plate forming a fold portion having one side end folded at a constant width along a bore edge;
And a shim stopper plate positioned in the folding direction of the grommet plate so as to be in contact with and interlock with the grommet plate between the full beads of the upper and lower bead plates.
The shim stopper plate is formed of a flat plate having a thickness smaller than the thickness of the grommet plate,
And a thickness of a range where the fold portion of the grommet plate is located is thicker than a thickness of a range where the shim stopper plate and the grommet plate are interviewed.
The method of claim 1,
The upper bead plate,
A bore side flat surface horizontal from the bore side;
A full bead concave from the bore-side flat surface;
A full bead-side flat surface extending from the full bead and having the same height as the bore-side flat surface;
An inclined surface inclined downward from the full bead side flat surface;
A cylinder head gasket having a double stopper structure, characterized in that it is constituted by an inclined surface side flat surface that is horizontal from the inclined surface.
The method of claim 1,
The lower bead plate,
A bore side flat surface horizontal from the bore side;
A full bead convex from the bore-side flat surface;
A full bead-side flat surface extending from the full bead and having the same height as the bore-side flat surface;
An inclined surface inclined upwardly from the full bead-side flat surface;
A cylinder head gasket having a double stopper structure, characterized in that it consists of a flat surface on the inclined side that is horizontal from the inclined surface.
delete The method of claim 1,
The grommet plate is folded in the direction of the lower bead plate, so that the shim stopper plate is positioned to interview the lower surface of the grommet plate, the cylinder head gasket having a double stopper structure.
6. The method of claim 5,
And the other side end of the grommet plate is engaged with the inclined side flat surface of the full bead plate, and the other side end of the shim stopper plate is located between the bead side flat surface.
6. The method of claim 5,
And the other side end of the grommet plate is engaged with the full bead side flat surface of the bead plate, and the other side end of the shim stopper plate is located between the inclined surface side flat surface.
The method of claim 1,
The grommet plate is folded in the direction of the upper bead plate, so that the shim stopper plate is positioned to interview the upper surface of the grommet plate, the cylinder head gasket having a double stopper structure.
The method of claim 8,
And the other side end of the grommet plate is engaged with the inclined side flat surface of the bead plate, and the other side end of the shim stopper plate is located between the full bead side flat surface.
The method of claim 8,
And the other side end of the grommet plate is engaged with the full bead side flat surface of the bead plate, and the other side end of the shim stopper plate is located between the inclined surface side flat surface.

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