The present invention relates to an unvulcanized rubber sheet for gasket material made of a compressible material for use in a base material of several kinds of gaskets, particularly to an unvulcanized rubber sheet for gasket material which is integrated on the surface of a metal plate or is used by itself and also to a manufacturing method thereof.
A gasket material formed by coating a compressible material layer on the surface of a metal plate has been widely used. An example of such gasket material is disclosed in JP-B-6-84785 in which a gasket material is formed such that a rubber compound layer mainly including a compressible base fiber material and a rubber material is formed on the surface of a metal plate by a vulcanization coating. This gasket material uses a metal plate as a base material, so that it has high strength, a dimensional accuracy in case of punching process with metal molds, and a superior working property for assembling into a sealing member. Further, because it has a layer of a compressible material, an embossing finish is easily executed. Still further, a rubber material does not drift because of carrying ability of base material fiber, and it has superior sealing ability and heat resistance, therefore it has been widely used as a base material of several kinds of gasket.
JP-A-9-11363 discloses a manufacturing method of the above-mentioned gasket material in which a metal plate coated with a heat resistant adhesive is inserted between a pair of rollers rotating in opposite directions, a rubber compound material including the above-mentioned compressible base fiber material is supplied between the metal plate and the roller, the metal plate passes between the rollers, and a rubber compound layer is vulcanized and coated on the surface of the metal plate. Further, JP-B-6-86075 and Japan Patent Number 2573932 disclose a method for obtaining a joint sheet in which a rubber compound material (rubber mixture) including fiber base material is supplied between a cold roller and a heated roller, the rubber compound material is heated and rolled on the surface of the heated roller, and the rolled rubber compound material is peeled off to obtain a joint sheet. In addition, a beater sheet is widely used as a sheet for a gasket material.
The gasket materials disclosed in JP-B-6-84785 and JP-A-9-11363 are widely used for vehicle engines, industrial machinery, mechanical component and the like. The gasket is practically prepared by punching the above-mentioned gasket material in an annular form according to the shape of an objective sealed portion, more particularly in the form including bolt holes. On account of such a shape characteristic of sealed portion, the inner punched-out portion (inside of annular shape) largely occupies the material, the rubber compound layer and the metal plate are joined with an adhesive, and the rubber material is vulcanized, so the inner punched-out portions and other punched-out portions cannot be reused and have little choice but to be discarded. Therefore, the gasket material incurs much waste, thereby causing high product cost.
The joint sheet or the beater sheet disclosed in JP-B-6-86075 and Japan Patent No. 2573932 is prepared separately from the metal plate, so that the punched-out portions of the metal plate can be reused. However, the joint sheet is formed such that the rubber is vulcanized at the time of heat rolling process and the punched-out portions are not reused as mentioned above. When they are reused by being crushed, such problem that its physical property is lowered may cause. Whereas the punched-out portions of the beater sheet can be reused, however, such problem that their fiber densities would become small further their thickness could not be reduced.
The present invention is proposed in order to solve the above-mentioned problems and the object of the present invention is to provide an unvulcanized rubber sheet for gasket material and its production method in which the characteristic of gasket material made of a compressible material is utilized to enhance its quality and in which waste materials at the time of production are reduced.
The present invention has the following effects.
When a sheet for gasket material of the present invention is used to be produced as a gasket, a separately prepared metal plate is punched into a predetermined shape, a heat resistant adhesive is applied on both surfaces of the metal- plate, and the gasket material sheet is punched in the same form to be attached on both surfaces of the metal plate by pressurization and compression. A mixture of unclosslinked synthetic resin and graphite is coated on both surfaces thereof according to the prior known method to form a graphite layer when necessary, a heat process is executed at the temperature of 140 to 160 degrees centigrade for 30-40 minutes, and an unvulcanized rubber material or rubber latex in the unvulcanized rubber sheet for gasket material is vulcanized or the uncrosslinked synthetic resin in the graphite layer is crosslinked to obtain a product. In this case, the metal plate is punched before being applied with adhesive or coated with a compound material, so that the punched-out portions can be reused without waste and the adhesive is applied only on a required portions, thereby reducing the amount of adhesive. Further, the unvulcanized rubber sheet for gasket material of which rubber material or rubber latex is unvulcanized condition is punched, so that the punched-out portions can be reused without waste and the used amount of graphite layer mixture is reduced, thereby remarkably reducing the production cost as a whole. Still further, because the metal plate or the gasket material sheet is separately punched, such a method is applicable to the case when the size of corresponding whole shapes and punch holes is preferably different, thereby improving adaptabilitas for various needs.
When a gasket is produced without integrating with a metal plate, the unvulcanized rubber sheet for gasket material is punched into a predetermined shape and the above-mentioned graphite layer is formed if necessary, and a desirable product can be obtained by executing the above-mentioned heat process. In such a case, waste materials such as the punched-out portions are not produced and the amount of graphite layer mixture is reduced. Further, the produced gasket has superior heat resistance because the rubber compound layer includes a base fiber material comprised of a compressible inorganic fiber except asbestos and a compressible organic fiber. Still further, the rubber compound layer hardly causes drifting and peeling, the torque retentiveness is superior and the characteristic of gasket material made of a compressible material is adequately utilized.
According to the first production method of unvulcanized rubber sheet for gasket material of the present invention, the above-mentioned unvulcanized rubber sheet for gasket material can be easily obtained. In case of the above-mentioned joint sheet, the rubber compound material is formed on the surface of heated roller by heat rolling and is peeled off the heated roller to obtain a product, so that a sheet larger than the surface area of the heat roller cannot be obtained. However, according to the present invention, a sheet of optional size is obtained by varying the size (length) of the metal plate, thereby achieving efficiency of production. Further, a spread layer of rubber compound material is formed on the surface of the metal plate under an unvulcanized condition, so that the spread layer can be made thin comparing to the joint sheet of prior art which is rolled while being heated and vulcanized.
According to the present invention in which at least one side of the metal plate on which the rubber compound material is to be supplied is so surface-treated as to facilitate peeling of the spread layer formed of rubber compound material, the spread layer is easily peeled off the metal plate, thereby contributing to keep product quality.
Further according to the production method of the present invention in which the providing step of a new spread layer of rubber compound material on the other surface of the metal plate is added between the forming step of the spread layer of rubber compound material and the peeling step of the spread layer of rubber compound material out of the metal plate to obtain a spread sheet of rubber compound material, the spread layer is formed on both surfaces of the metal plate before peeling off the spread layer from the metal plate, thereby improving the efficiency of production process.
Still further according to the production method of the present invention in which the thickness control step for the spread layer is added between the forming step of the spread layer of rubber compound material and the peeling step of the spread layer of rubber compound material out of the metal plate to obtain the spread sheet of rubber compound material, the rubber compound material of the spread layer is optionally compressed because it is still unvulcanized, so that a thin sheet can be obtained comparing to the prior method and the applicable scope as a gasket material can be enlarged.
Further according to the second production method of the unvulcanized rubber sheet for gasket material of the present invention, the above-mentioned rubber compound material is supplied into a feeding portion of a pair of rollers which rotate in opposite directions each other at a circumferential speed ratio of 1:1.01 to 1.2 (preferably 1:1.05) so as to be spread, so that a thin spread sheet can be fed out without adhering on the surfaces of both rollers. When the circumferential speed ratio is 1:less than 1.01 to 1, the spread sheet tends to be adhered on the roller of lower circumferential speed. When it is 1:more than 1.2, the spread sheet is apt to be broken. The fed out spread sheet made of unvulcanized rubber compound material is passed through the fitting portion of the pair of gauge control rollers which are arranged at a predetermined space, so that a thin spread sheet of desirable thickness comparing to the prior arts can be surely obtained, thereby enlarging the applicable scope as a gasket material. Still further according to the present invention in which the second gauge control process is added after the above-mentioned gauge control process, a thinner spread sheet can be optionally obtained. Further, according to the present invention in which the above-mentioned surface process is executed on the surface of each roller, the adherability of rubber compound material passing through the fitting portion of the rollers onto the surfaces of the rollers is reduced and the spread sheet can be smoothly fed out.
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The preferred embodiments of the present invention are explained referring to the attached drawings.
The compressible inorganic fiber comprising the compound material may be a: glass fiber; ceramic fiber; rock wool; mineral wool; fused quartz fiber; chemical processed high silica fiber; fused alumina silicate fiber; alumina continuous fiber; stabilized zirconia fiber; boron nitride fiber; alkali titanate fiber; whiskers; boron fiber; carbon fiber; metal fiber; or the like. The compressible organic fiber may be an: aromatic polyamide fibers; other polyamide fibers; polyolefine fibers; polyester fibers; polyacrylonitrile fibers; polyvinyl alcohol fibers; polyvinylchloride fibers; polyurea fibers; polyurethane fibers; polyfluorocarbon fibers; phenol fibers; cellulosic fibers; or the like.
The rubber comprising the compound material may be a: nitrile rubber (NBR); styrene-butadiene rubber (SBR); isoprene rubber (IR); chloroprene rubber (CR); butadiene rubber (BR); isobutylene-isoprene rubber (IIR); ethylene propylene rubber (EPM); fluoro rubber (FKM); silicone rubber (Si); chlorosulfonated polyethylene (CSM); ethylene-vinylacetate copolymer (EVA); chlorinated polyethylene (CPE); chloro-isobutene-isoprene rubber (CIIR); epichlorohydrin rubber (ECO); nitrile isoprene rubber (NIR); natural rubber (NR); or the like. Oil extended rubbers that are obtained by adding oil to these rubbers, such that naphthenic process oil is added to SBR, may also be used within the scope of this disclosure.
The rubber agent may be a vulcanizing agent such as sulfur, zinc oxide, magnesium oxide, peroxide, dinitrobenzene, or the like. Further, a vulcanization accelerator such as: thiazole compounds; polyamine compounds; sulfonamide compounds; dithiocarbamate compounds; aldehydeamine compounds; guanidine compounds; thiourea compounds; xanthate compounds; or the like, may be used. The inorganic filler may be a: clay; talc; barium sulfate; sodium bicarbonate; graphite; sulfate; tripoli; wollastonite; or the like. Toluene is preferably used as solvent and is contained in the rubber compound material 3 in the amount of 10 40 percent by weight. Water is used for rubber latex.
The space between the rollers 2a, 2b is arranged such that the thickness of a spread layer 3a (see
a and
According to the embodiment in
It is not shown in the figure, however, a gauge control process may be added between the drying process and the peeling process of the spread layer 3a (3a of rubber compound material from the metal plate 1 to obtain the spread sheet 3b of rubber compound material, and the metal plate 1 formed with the spread layer 3a (3a′) of rubber compound material passes through a fitting portion of a pair of gauge control rollers (the rollers 2a, 2b may be also used) to compress the spread layer 3a (3a of rubber compound material to control the thickness. The spread layer 3a (3a′) does not have a rubber elasticity yet, so that a thinner spread sheet 3b may be optionally obtained by adding such a gauge control process.
In the figure, the second drying zone 10 and the second gauge control rollers 11 (11a, 11b) are sequentially provided next to the gauge control roller 9. The spread sheet 3d is further compressed to obtain a spread sheet 3e with 50 200 m thickness. The rubber material or rubber latex of the spread sheet 3c fed out of the rollers 7a, 7b is unvulcanized, so that optional gauge control can be executed with the gauge control rollers 9a, 9b and the second gauge control rollers 11a, 11bwhich are provided at downstream, thereby obtaining a thin spread sheet 3e which cannot be obtained by the prior joint sheet. The spread sheet 3e is rolled up by a drum (not shown) as a product sheet for gasket material.
The surface of the rollers 7a, 7b are coated (surface-treated) with a low-friction material as mentioned above. The circumferential speed ratio of the rollers 7a, 7b is set as mentioned above. Thus, the rubber compound material 3 is prevented from adhering on the rollers 7a, 7b. This embodiment of production method is characterized in that the metal plate 1 is not required as mentioned in the above embodiments and a preferable embodiment is selectively used.
The sheet for gasket material obtained according to the production method of the present invention is punched-out as mentioned above, or is integrated with a metal plate, and further is graphite processed to be heated or vulcanized. The resultant product is widely used for a cylinder head gasket of vehicle engine, several kinds of gasket for internal combustion engine, and other portions to be sealed. The sheet of the present invention is so thin comparing with the prior products that its applicable utilization is enlarged. Further, the production process in the embodiments mentioned above includes a drying process, however, a drying process may not be required depending on the amount of solvent contained in the rubber compound material and the temperature of rollers.
Although only preferable embodiments of the present invention have been disclosed and described, it is apparent that other embodiments and modification of the invention are possible.
Number | Date | Country | Kind |
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2005-298329 | Oct 2005 | JP | national |