Metal laminate gasket for open deck type engine

A metal laminate gasket of the invention is designed to be installed on an open deck type engine. The gasket is basically formed of first and second metal plates. A thin metal plate is installed between the metal plates to be situated above a main body or frame outside cylinder walls of the engine. Accordingly, when the gasket is tightened, high surface pressure is formed on the main body outside the water passage to securely seal outside the water passage.

BACKGROUND OF THE INVENTION AND RELATED ART STATEMENT 
The present invention relates to a metal laminate cylinder head gasket for 
an open deck type engine. 
A light weight automobile engine has been developed to provide high power. 
In order to satisfy this demand, a cylinder block may be made of an 
aluminum alloy, and in some cases, formed by die casting to become an open 
deck type, so that the molded cylinder block can be easily removed from 
the die. 
One example of the open deck type cylinder block 10 is shown in FIG. 1. The 
cylinder block 10 is formed integrally as one unit, and includes cylinder 
walls 12 for defining cylinder bores 11 therein and an outer frame or main 
body 13. The cylinder walls 12 are connected together at connecting 
portions 14. The cylinder walls 12 are also connected to the outer frame 
13 at bottom portions 14' thereof, and form therebetween a space 15. 
Cooling liquid or water circulates through the space 15 for cooling the 
cylinder bores 11. 
The outer frame 13 includes bolt holes 16 for connecting with a cylinder 
head (not shown). Also, an oil hole 17 is formed in the outer frame 13 for 
circulating oil. As shown in FIG. 2, cylinder liners 18 may be installed 
inside the cylinder walls 12. 
In order to seal the open deck type engine, a gasket 20 is used. The gasket 
20 is formed of an upper plate 21, a middle plate 22, and a lower plate 
23. The upper plate 21 includes a water hole 21a, a curved portion 21b for 
defining the cylinder bore 11, and a flange 21c. The middle plate 22 
includes a water hole 22a, and beads 22b, 22c extending along the space 15 
for sealing at side portions of the space 15. The lower plate 23 includes 
a water hole 23a, and a bead 23b extending around the cylinder bore 11 for 
sealing therearound. 
In the conventional gasket 20, coatings may be formed on the entire outer 
surfaces of the gasket for sealing and filling out small scratches formed 
on the cylinder block and the cylinder head. Further, soft seal coatings 
may be formed on the entire surfaces of the middle plate to prevent liquid 
from flowing between the plates. 
However, in case the soft seal coating is formed on the entire outer 
surfaces of the middle plate, a part of the coating formed on the beads 
may wear or be broken, because the cylinder wall 12 vibrates severely. 
In U.S. Pat. No. 4,968,045, a plate for forming a gasket is made so that a 
portion of the plate for contacting cooling liquid does not have a seal 
coating. As a result, the seal coating does not enter into the cooling 
liquid, and consequently, clogging of a water circulating system of an 
engine is prevented. 
In the open deck type engine, the cylinder walls vibrate severely, so that 
if the coating is formed on the cylinder PG,4 wall, the coating may wear 
or break. None of the prior art gaskets solves this problem. 
Accordingly, one object of the present invention is to provide a metal 
laminate gasket for an open deck type engine, wherein an area around a 
water hole is securely sealed. 
Another object of the invention is to provide a metal laminate gasket as 
stated above, which can be easily and economically manufactured. 
Further objects and advantages of the invention will be apparent from the 
following description of the invention. 
SUMMARY OF THE INVENTION 
In the present invention, a gasket is installed in an engine with an open 
deck type cylinder block. The cylinder block includes a plurality of 
cylinder walls for defining cylinder bores, a main body or frame and a 
water passage for surrounding the cylinder walls inside the main body. 
The gasket basically comprises first and second metal plates, and a thin 
metal plate situated between the metal plates. The thin metal plate 
extends substantially above the main body outside the cylinder walls. 
Accordingly, when the gasket is tightened, high surface pressure is formed 
on the main body outside the water passage to thereby securely seal 
outside the water passage. 
The gasket further includes a plurality of first sealing means or inner 
beads located on or above the cylinder walls for sealing around the 
cylinder bores, and second sealing means or an outer bead located on or 
above the main body for surrounding the water passage to seal therearound. 
Another bead may be formed above the cylinder walls to surround the water 
passage between the two beads. Preferably, the thin metal plate is located 
outside the outer bead. 
In case a soft coating is formed on the entire surface of the middle plate, 
the inner beads located on the cylinder wall contact the soft coating. 
Since the cylinder walls are not securely held by the bolts, when the 
engine is operated, the cylinder walls vibrate severely. As a result, the 
soft coating located above the cylinder walls wears and causes leakage 
thereat. 
In the present invention, the thin metal plate is located on the main body, 
not on the cylinder walls. Therefore, even if the cylinder walls vibrate 
severely, the thin metal plate is not affected by the vibration. Also, the 
thin metal plate increases the surface pressure on the main body. 
Therefore, leakage of water from the water passage is prevented. 
Further, in case the thin metal plate is located on the main body, when the 
gasket is tightened, the surface pressure on the main body can be 
increased without affecting the surface pressure applied onto the cylinder 
walls. Namely, balance of the surface pressures applied on the main body 
and the cylinder walls can be controlled by selecting the thickness of the 
thin metal plate. 
Fox example, when the thin metal plate is located on the side of the bead, 
the surface pressure on the bead is reduced, because the thin metal plate 
operates as a surface pressure regulation plate. On the other hand, when 
the thin metal plate is located on the opposite side of the bead, the 
surface pressure on the bead is not changed by the thin metal plate. 
However, the balance of the surface pressures on the main body and the 
cylinder walls is changed by the thin metal plate. 
If desired, a soft seal coating may be formed on one or both sides of the 
thin metal plate. In this case, the soft seal coating must not expose the 
water passage.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
Referring to FIG. 3, a gasket A of the invention is shown. The gasket A is 
designed to be installed on an engine 10 as shown in FIG. 1. 
The gasket A is formed of an upper plate A30, a middle plate A31, and a 
lower plate A32. The upper plate A30 includes a plurality of water holes 
A30a, curved portions A30b for defining the cylinder bores 11, and flanges 
A30c (not shown). 
The middle plate A31 includes a plurality of water holes A31a (not shown), 
a bead A31b and a bead A31c. The bead A31b is situated above the cylinder 
walls 12 and extends along the space 15 for cooling water. The bead A31c 
is situated above the frame 13 and extends along and outside the space 15. 
When the gasket A is tightened, the beads A31b, A31c provide surface 
pressure for sealing around the space 15. 
The lower plate A32 includes a plurality of water holes A32a, and beads 
A32b to seal around the cylinder bores 11. The bead A32b is located above 
the flange of the upper plate A30. 
The gasket A further includes a thin metal plate A33 situated above the 
middle plate A31 outside the bead A31c. The thin metal plate A33 provides 
surface pressure on the frame 13 when the gasket A is tightened. In the 
gasket A, bolt holes 16' and an oil hole 17' are also formed. 
In the gasket A, the thickness of the thin metal plate A33 is between 
0.02-0.15 mm, and the thin metal plate may be made of any kind of metals 
for the gasket. The other plates may have thicknesses between 0.15-0.3 mm. 
When the gasket A is situated between the cylinder block 10 and a cylinder 
head (not shown) and is tightened, the beads A32b are compressed to seal 
around the cylinder bores 11, and the beads A31b, A31c are compressed to 
seal around the space 15. Since the thin metal plate A33 is located on the 
middle plate A31, high surface pressure is formed on the frame 13. 
Therefore, leakage of water from the space 15 is substantially prevented. 
In the gasket A, the thin metal plate A33 is situated above the middle 
plate A31 outside the bead A31c. Therefore, the metal plate A33 operates 
as a surface pressure regulation plate for the beads A31b, A31c, A32b. 
When the gasket A is tightened, therefore, the surface pressures on the 
frame 13 and the cylinder walls 12 and the balance thereof can be 
controlled by selecting the thickness of the thin metal plate A33. 
In case the thin metal plate A33 is situated under the middle plate A31, 
the metal plate A33 also affects the surface pressure for the beads A31b, 
A31c, A32b. 
Therefore, the thin metal plate A33 helps secure sealing around the water 
passage. Also, surface pressures formed on the beads or on the cylinder 
walls can be properly controlled by selecting the thickness of the thin 
metal plate A33. 
Further, in case the thicknesses or hardnesses of the middle plate A31 and 
the lower plate A32 are changed, surface pressures formed on the beads 
A31b, A31c and the bead A32b can be controlled. The desired surface 
pressures are formed on the beads A31b, A31c, A32b. 
FIGS. 4 and 5 show a second embodiment B of the gasket of the invention. 
The gasket B includes an upper plate B30 with water holes B30a, curved 
portions B30b and flanges B30c, a middle plate B31 with water holes B31a, 
and a lower plate B32 with water holes B32a, as in the gasket A. 
In the gasket B, the middle plate B31 is provided with an inclined wall or 
embossment B31c situated above the frame 13, but the middle plate B31 does 
not have a bead on the cylinder wall 12. Also, the lower plate B32 does 
not have a bead on the cylinder wall 12, and instead, a wire ring B34 is 
installed for sealing around the cylinder bore. 
Further, a thin metal plate B33 with a soft coating B33a is placed on the 
middle plate B31. The soft coating B33a may be silicone resin, fluorine 
resin, silicone gum, fluorine gum, NBR and so on. 
In the gasket B, the width of the cylinder wall 12 is made relatively 
narrow. Therefore, the wire ring B34 is installed above the cylinder wall 
12. The wire ring B34 and the embossment B31c can securely seal around the 
cylinder bores and the water passage. 
In the gasket B, since the soft coating B33a is formed on the thin metal 
plate B33, sealing between the plates B30, B33 is enhanced. The coating 
B33a may be formed on both sides of the thin metal plate B33. Also, in the 
gasket B, the thin metal plate B33 may be formed under the middle plate 
B31. The gasket B operates as in the gasket A. 
FIG. 6 shows a third embodiment C of the gasket of the invention. The 
gasket C includes an upper plate C30 with water holes C30a, curved 
portions C30b and flanges C30c, a thin metal plate C33, and a lower plate 
C32 with water holes C32a and beads C32b, C32c. 
In the gasket C, the flange C30c and the bead C32b are located on the 
cylinder wall 12 to seal around the cylinder bore, and the bead C32c is 
located on the frame 13. The water holes are securely sealed by the beads 
C32b, C32c. The gasket C operates as in the gasket A. 
In the present invention, the thin metal plate is situated between the 
plates and located above the frame and outside the cylinder wall. 
Therefore, when the gasket is tightened, the surface pressure of the 
gasket above the frame is increased to seal outside the water passage. 
Since the thin metal plate is not formed above the cylinder walls, even if 
the cylinder walls vibrate severely, it does not affect the sealing 
outside the water passage. 
Further, the surface pressures on the frame and the cylinder walls can be 
easily controlled by selecting the thickness of the thin metal plate. 
Also, the surface pressures on the beads around the cylinder bore and 
water passage can be easily controlled. 
While the invention has been explained with reference to the specific 
embodiments of the invention, the explanation is illustrative, and the 
invention is limited only by the appended claims.