KR20090080765A - A structure using double caulking for gasket - Google Patents

Abstract

A double coupling structure of a laminate-type gasket is provided to couple plates strongly and to secure structural stability, and to relieve stress concentration and crack formation caused by vibration on the end of a cutting line. A double coupling structure(100) of a laminate-type gasket includes facing cutting lines formed on the same location in each plate of plural plates(1a,1b) forming a laminate-type gasket, a caulking section formed by pressurizing the space between the cutting lines, a second cutting line(130) formed at a certain space on two ends of the cutting line, and a second caulking section(140) formed by pressurizing a plate surrounded with the second cutting line, wherein a first incline(122a) and a second incline(122b) forming an upward gradient are formed on two ends of the bottom(121) of the caulking section to relieve stress concentration on the end of the cutting line.

Description

Double bonding structure of laminated gasket. {A STRUCTURE USING DOUBLE CAULKING FOR GASKET}

1 is a cross-sectional view showing a coupling structure in a laminated gasket according to the prior art,

2 is a plan view showing a plate according to an embodiment of the present invention,

3A is a plan view corresponding to portion A in FIG. 2,

3B is a cross-sectional view taken along line A-A of FIG. 2,

4A and 4B are cutaway perspective views illustrating a coupling structure of a laminated gasket according to the present invention.

5 is a plan view showing another embodiment of the present invention.

    ♣ Explanation of symbols for main part of drawing ♣

1a, b: plate 110: perforation line

111: protrusion line 120: caulking unit

121: bottom 122: inclined surface

130: second cutting line 140: second caulking unit

The present invention relates to a double coupling structure of a laminated gasket, and more particularly, in a laminated gasket for coupling a plurality of plates by respective caulking parts, each of the second caulking parts spaced at regular intervals in both directions of the caulking part. The present invention relates to a coupling structure of a laminated gasket capable of relieving stress concentration at an end of a perforated line for constructing a caulking portion by constructing a two-step inclined surface by strengthening fastening and structural stability.

In general, a gasket is inserted between a component or a mating surface or contact surface between fluid and gas, such as an engine (internal combustion engine), an oil / pneumatic device, to prevent leakage from being leaked. .

In particular, the gasket is applied to an engine part such as a vehicle. In the engine of the vehicle, in particular, the gasket is installed between the contact surface of the cylinder block and the cylinder head and between the contact surface of the cylinder head and the cylinder head cover. It is in charge of and prevents leakage of high pressure combustion gas in the combustion chamber. The interior of the combustion chamber is in a mechanical environment where the pressure inside the cylinder changes continuously during the four-stroke cycle of compression, expansion, explosion, exhaust, and the like.

In particular, the internal gas pressure during the explosion is so high that it exceeds the clamping force of the bolt coupling between the cylinder head and the cylinder block, so the cylinder head is pushed upward (lift-up force). Is generated so that a small gap exists between the gasket and the cylinder head to the cylinder block.

For example, in a compression ignition engine, when the cylinder head is lifted up by 10 μm (0.01 mm) to 15 μm (0.015 mm) in height from the top of the cylinder block when subjected to a lift force, the fluid gap is between the cylinder head and the cylinder block. Will make

At this time, since the internal gas pressure is approximately 200 times the atmospheric pressure, the internal gas is counted outside through the gap, which adversely affects the combustion efficiency of the internal combustion engine.

Since the minute gap changes fluidly with the change of load inside the cylinder during the cycle, a laminated and flexible gasket is required to maintain a satisfactory seal in the internal combustion engine and to suppress the formation of a fine gap generated during explosion. Do.

In general, laminated gaskets have been used in which a plurality of metal sheets (plates) are laminated and bonded.

For example, the laminated gasket may be composed of two plates, and a bead plate having a bead formed to allow the joint surface of the cylinder head and the cylinder block to be sealed by elastic force, and a decrease in sealing performance due to complete compression of the bead of the bead plate. It can be configured as a stopper plate to prevent it.

As such, there are basically methods for laminating and joining two plates, such as grommets, hemmings, and jags, which have been mainly used so as not to be separated from each other by riveting, yag welding, and the like.

However, when the plates are coupled to each other by riveting as described above, a separate riveting work is required, and in the case of yag welding, thermal stress is generated on the plate assembled by heat generated by welding. Thermal deformation occurs in the laminated gasket assembled by this thermal stress, which also has to be a separate welding process.

Due to this problem, as shown in Figure 1 by using the caulking unit (method) is used to combine the plates with each other, the caulking method is configured to correspond to each plate by caulking correspondingly without a separate riveting or welding process By inserting the caulking, the plates are joined to each other.

However, in the case of the caulking method, as shown in Figure 1, there is a problem in that the sliding is generated between the plates by simply inserting the caulking portion between the plates to hinder the function of the gasket, the perforated line to form the caulking portion At the ends of these perforations, stress concentration is caused and there are structural problems such as cracks caused by vibrations.

Therefore, in order to solve the above-mentioned weakness, the present invention provides a rigid coupling structure that prevents slippage when joining a plurality of plates by respective caulking portions, stress concentration formed at the end of the perforated line, and cracks due to vibration. It is to provide a coupling structure of a laminated gasket that can be relaxed.

In order to achieve the above object, the present invention is a coupling structure of a laminated gasket composed of a facing cut line formed at the same position on each plate in a plurality of plates constituting the laminated gasket and a caulking portion formed by pressing between the cut lines. A second cutting line formed at positions spaced apart from both ends of the cutting line; The second cutting line is characterized by consisting of a second caulking portion formed by pressing the plate portion wrapped.

Each of the opposing cut lines is configured to have a shape narrowing in both end directions.

The second cutting line includes a pair of horizontal lines formed in a direction in contact with the pair of cutting lines and a vertical line formed integrally with the horizontal lines and formed in a direction perpendicular to each horizontal line. The second caulking portion may be inclined in the opposite direction to the caulking portion by a cut line.

The height h1 protruding from the plate in the second caulking portion may be configured to be smaller than a plurality of plate heights h2 constituting the laminated gasket.

Each horizontal line in the second cutting line is formed in a shape widening in the opposite direction to the caulking portion, characterized in that the second caulking portion is configured in the lower narrow light shape.

The caulking portion is characterized in that the bottom portion and the two inclined surfaces are formed at both ends of the bottom portion.

Hereinafter, with reference to the accompanying drawings it will be described in detail with respect to the double coupling structure of the laminated gasket according to an embodiment of the present invention.

1 is a cross-sectional view showing a coupling structure in a laminated gasket according to the prior art, Figure 2 is a plan view showing a plate as an embodiment of the present invention, Figure 3a is a plan view corresponding to the portion A in Figure 2, Figure 3b is a cutaway cross-sectional view corresponding to the AA portion in Figure 2, Figures 4a and 4b is a cutaway perspective view showing a coupling structure of the laminated gasket by the hook of the present invention, Figure 5 is a plan view showing another embodiment of the present invention to be.

According to the present invention, in a laminated gasket composed of a plurality of plates, a rigid coupling force is provided by a double caulking portion in a coupling structure between the plurality of plates, and at the same time, a two-slope inclined surface is formed in the caulking portion to alleviate stress concentration. .

On the other hand, the present invention is a structure that is applied to a case consisting of a plurality of plates in the following as an example of a laminated gasket composed of a plurality of plates as shown in Figures 2 to 4 laminated gaskets into two plates (1a, 1b) The configuration case will be described as an example.

As shown in FIG. 2, the general plate 1 has a predetermined number of bores 7 (for example, applied to a four-cylinder cylinder) according to the number of cylinder cylinders of an internal combustion engine. Is formed. A coolant supply hole 8 and an oil supply hole 6 for cooling the cylinder and supplying lubricating oil are formed at the outer edges of the bores, that is, between the bore and the edge of the plate. In addition, the plate 1 is provided with a bolt insertion hole 9 for fastening to the cylinder block (not shown) and the cylinder head (not shown).

In addition, the plate 1 is formed in the periphery of the bore (7) bore bead (3) to prevent the leakage of the combustion gas by the elastic force, the oil around the oil supply hole (7) to prevent leakage of high pressure oil A bead 4 is formed, and a side bead 5 formed at a predetermined distance from the end is formed along the bead plate edge to prevent leakage of combustion gas, oil coolant, etc. from the joint surface of the cylinder block and the cylinder head. will be. Such beads may not be configured in the case of stopper plates.

In addition, the coupling structure 100 for laminating and bonding between the plates 1, that is, the present invention is formed in the A portion. Coupling structure 100 of the present invention is a plurality of plates (1a, 1b) constituting a laminated gasket facing the perforation line 110 is formed at the same position (part A) on each plate (1a, 1b), and It consists of a caulking portion 120 formed by pressing between the cutting line. The caulking unit 120 is configured by pressing a portion between the cutting lines 110 by forming a pair of cutting lines 110 facing the plates 1a and 1b, respectively, as shown in FIGS. 4A and 4B. The mountain portion of the caulking portion 120 formed in (1a) is inserted into the valley portion of the caulking portion 120 formed in the lower plate (1b) is to join the respective plates (1a, 1b).

In addition, in the present invention, the pair of perforated lines 110 facing each other are configured to be narrowed in both end directions in order to prevent slippage in insertion and fastening by the caulking portion 120 between the plates. That is, as shown in FIG. 3A, the bottom portion 121 of the caulking portion 120 is formed in the center portion, that is, in a portion that is narrowed in the direction of both ends of the cutout line 110 by pressing, and is formed in the caulking portion 120. The inclined surface 122 to be described below is to be configured in a shape that narrows in the upper direction.

Here, the widths (lengths) d1, d2, and d3 of the inclined surface 122 formed at both ends of the bottom portion 121 and the bottom portion 121 of the caulking portion 120 are configured to be the same. It will be advantageous to, and in order to increase the locking effect of the caulking portion 120, it is preferable to configure the width (length) d1, d3 of each inclined surface 122 larger than the width (length) d2 of the bottom portion 121. . Therefore, it is natural that each of the widths (lengths) d1, d2, and d3 can be selectively configured.

In particular, the present invention is composed of a second cutting line 130 and the second caulking portion 140 is formed by pressing the plate portion that is wrapped around the second cut line 130 formed at both ends of the cut line 110, As shown in FIG. 3A, the second cutting line 130 is configured to face each other in a "c" shape in a state where a predetermined distance is separated from both ends of the cutting line 110. In more detail, the second cutting line 130 is formed integrally with the pair of horizontal lines 131 and the horizontal lines 131 which are formed to be spaced apart from the pair of cutting lines 110. It consists of a vertical line 132 is formed in a direction perpendicular to the horizontal line of 131, the second caulking portion 140 by the second cut line 130 is inclined gradient in the opposite direction to the caulking portion 120, respectively It may be configured to be formed.

In addition, as shown in FIG. 3A, each of the horizontal lines 131 in the second cutting line 130 is preferably configured to have a shape widening in the opposite direction to the caulking part 120. By configuring as described above, the second caulking portion 140 is configured to have a lower narrow light shape, and the shape of the second caulking portion 140 prevents slippage between the plates, thereby enabling firm fastening. In addition, it is preferable to configure the horizontal line 131 and the vertical line 132 to be in contact with the round so that the corner of the second caulking unit 140 is rounded so as to prevent stress concentration by the round surface. Do.

On the other hand, as shown in Figure 5 as another embodiment of the present invention may be configured to form a concave curvature in the center direction in the vertical line (132a) in the second caulking unit 140. The fastening by the second caulking unit 140 is made more robust by the configuration of the vertical line 132a.

The second caulking portion 140 in the same direction as the protruding direction of the caulking portion 120 at the same time as the caulking portion 120 at the same time as the caulking portion 120 in the same projecting direction as the caulking portion 120 in both directions. By configuring the coupling structure 100 of the present invention is to enable a solid fastening by the double caulking portion.

In addition, in the present invention, the second caulking portion 140 is configured to generate at the end of the cutting line 110 by forming a second bending line b parallel to the bending line a of the caulking portion as shown in FIG. 3A. The one-way propagation of the crack due to vibration can be canceled out.

In addition, the height h1 of the second caulking portion 140 protruding from the plate, that is, the height h1 of the second caulking portion 140 protruding below the lower plate 1b is stacked as shown in FIG. 3B. It is preferable that it is smaller than the total height h2 of the several plates 1a and 1b which comprise a gasket. In this way, the end of the second caulking unit 140 is in contact with the cutting surface by the vertical lines 132, 132a of the second cutting line 130 to be firmly held without slipping between the plates.

On the other hand, the caulking portion 120 is formed with an inclined surface 122 to form an upward inclination gradient at both ends of the bottom portion 121 is composed of a smooth surface may be configured to connect with the flat portion (2) of the plate. Particularly, in the present invention, the inclined surface 122 is formed at both ends of the bottom portion 121 to form an upward inclined gradient, but the inclined surface 122 may be configured in two stages for structural stability. That is, as shown in FIGS. 3A to 3B, structural problems may occur due to stress concentration at both ends of the perforated line 110, that is, at four ends. As another embodiment of the present invention, two steps may be used in 4A and 4B. An embodiment of forming the inclined surface 122 is shown. That is, the first inclined surface 122a which forms an upward inclined gradient at both ends of the bottom portion 121 is formed, and the second inclined surface 122b which forms an inclined gradient but forms an inclined gradient smaller than the first inclined surface 122a. ) To form. By forming the second inclined surface 122b as described above, stress concentration can be alleviated at the end of the cutting line 110.

Hereinafter, with reference to the drawings will be described the operating state of the present invention. In the plate-to-plate coupling structure 100 of the present invention, a cut line 110 and a second cut line 130 are formed at each of the plates 1a and 1b, and as shown in FIG. The second cutting line 130 is formed in both directions of the cutting line 110 and 110. However, the perforation line 110 is configured to have a shape in which the center portion is convexly expanded to narrow the end, and the second perforation line 130 is narrowed in the end direction to the horizontal line 131 extending in parallel with the perforation line 110. To configure the horizontal line 131 and the vertical line 132 is in contact with the corner rounded.

In the state in which both plates 1a and 1b are stacked, a portion between the cutting line 110 and a portion of the second cutting line 130 is pressed to form a caulking part 120 and a second caulking part 140. The caulking portion 120 may be formed by pressing so that the inclined surface 122 is formed at both ends of the bottom portion 121 and the bottom portion 121 of the smooth surface to have a trapezoidal shape at the side cross section, and the second caulking portion 140 ) Is configured to press the caulking portion 120 to protrude in the same direction as the protruding direction so that each second caulking portion 140 is formed to be inclined gradient in the opposite direction to the caulking portion 120.

As described above, the second caulking portion 140 is formed in both directions of the caulking portion 120 to strengthen the fastening force, and as shown in FIG. 3A, the bent portion a and the second caulking portion 140 by the caulking portion 120 are provided. By forming the second bent portion (b) in parallel to the parallel to prevent the one-way propagation of the crack caused by the vibration generated at the end of the cutting line (110) to provide a structurally stable coupling structure.

In addition, in forming the second caulking portion 140 by pressing, the height h1 of the second caulking portion 140 protruding from the plate may include a plurality of plates constituting the laminated gasket (see FIG. 3B). 1a, 1b) It is configured to be smaller than the total height (h2) so that the end of the second caulking portion 140 is in contact with the cutting surface by the vertical line 132 of the second cutting line 130, without slipping between the plates without slipping To hold on to it.

Meanwhile, in forming the inclined surface 122 in the caulking unit 110, as shown in FIGS. 4A and 4B, two inclined surfaces 122a and b may be formed. Thus, the first inclined surface 122a and the first inclined surface 122a may be formed. By forming the two inclined surfaces 122b, the stress concentration can be alleviated at the end of the perforated line 110, so the present invention provides a structurally stable coupling structure.

The above-mentioned information exemplifies a case in which only two plates of the laminated gasket are configured, and the present invention is not limited thereto. In the stacking gasket applying the coupling method, the double caulking unit is configured to provide a firm coupling between the plates, and to provide a structurally stable coupling structure by constructing two inclined surfaces at each caulking unit.

The double coupling structure of the laminated gasket of the present invention has the advantage of enabling a rigid coupling between the plates by configuring a double caulking portion on the plurality of plates.

The double coupling structure of the laminated gasket of the present invention has a bending portion formed by the caulking portion and the second bending portion formed by the second caulking portion in parallel to prevent the one-way propagation of the crack caused by the vibration generated at the end of the cutting line structurally There is also a stable advantage.

In addition, the double coupling structure of the laminated gasket of the present invention has a structurally stable advantage by forming a two-slope inclined surface of each caulking portion to relieve stress concentration at the end of the cutting line.

The technical concept of the double bond structure of the laminated gasket of the present invention described above has been described with the accompanying drawings, but this is only illustrative of the best embodiments of the present invention and is not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (7)

In the coupling structure of the laminated gasket composed of a facing cut line formed at the same position on each plate in a plurality of plates constituting the laminated gasket and a caulking portion formed by pressing between the cut lines, Second cut lines formed at positions spaced apart from both ends of the cut lines; Double coupling structure of the laminated gasket, characterized in that the second caulking portion formed by pressing the portion of the plate wrapped around the cutting line. The method of claim 1, The opposing cut line is a double coupling structure of a laminated gasket, characterized in that each configured in a shape that narrows in the direction of both ends. The method of claim 1, The second cutting line includes a pair of horizontal lines formed in a direction in contact with the pair of cutting lines and a vertical line formed integrally with the horizontal lines and formed in a direction perpendicular to each horizontal line. The double coupling structure of the laminated gasket, characterized in that the inclined gradient is formed in the opposite direction to each of the caulking portion by the cutting line. The method of claim 3, wherein And a height h1 of the second caulking portion protruding from the plate is smaller than the total height h of the plurality of plates constituting the laminated gasket. The method of claim 3, wherein Each of the horizontal lines in the second cutting line is formed in a shape that widens in the opposite direction to the caulking portion is a double coupling structure of the laminated gasket, characterized in that the second caulking portion is configured in the lower narrow light shape. The method of claim 3, wherein The double coupling structure of the laminated gasket, characterized in that the vertical line in the second cutting line is formed a concave curvature in the center direction. The method of claim 1, Double-coupling structure of the laminated gasket, characterized in that the caulking portion is formed with two inclined surfaces at both ends of the bottom portion and the bottom portion.

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