The present invention relates to a method for manufacturing a pneumatic tire in which the raw tire is built by the use of an uninflatable core mold in stead of a conventional inflatable bladder and expandable tire building drum.
In recent years, as part of countermeasures to global warming, there is urgent need to improve fuel consumption performance of automobiles. Therefore, tire manufacturers are strongly required to decrease the rolling resistance as well as the weight of a pneumatic tire.
As well known, a pneumatic tire is manufactured by building a raw tire and vulcanizing the raw tire in a mold. In general, the raw tire is built by applying various tire components onto an expandable tire building drum, and the built-up raw tire is put in a mold, and the inside of the tire is pressurized by inflating a bladder disposed inside the tire.
Thus, during manufacturing the raw tire, the air-impermeable inner liner covering the inner surface of the tire is often pressed against the adjacent carcass cords. Therefore, the inner liner has to have some degree of thickness to secure the required thickness covering the carcass cords.
In order to decrease the weight of the inner liner rubber, if the thickness of the inner liner is reduced, since the covering thickness is decreased, there is a possibility that the carcass cords are almost exposed and the air sealing effect is impaired. Further, there is a possibility of decreasing the tire durability. Accordingly, it is difficult to reduce the weight of the inner liner rubber.
It is therefore, an object of the present invention to provide a method for manufacturing a pneumatic tire in which, the weight of the inner liner rubber can be decreased to reduce the weight of the tire, and even if the weight of the inner liner rubber is decreased, the above-mentioned problems with the exposure of the carcass cords, and the deterioration in the air sealing effect and the tire durability can be solved.
The manufacturing method according to the present invention is for a pneumatic tire comprising a carcass ply made of carcass cords rubberized with topping rubber and extending between bead portions of the tire. The method comprises
a raw tire building process for building a raw tire on an annular surface of an uninflatable core mold, and
a vulcanizing process for vulcanizing the raw tire built on the core mold by heating the raw tire together with the core mold, wherein
the raw tire building process comprises
rubberizing the carcass cords with the raw topping rubber, and
making the raw carcass ply by the use of the rubberized carcass cords,
the carcass cords are made of polyethylene terephthalate or alternatively polyethylene naphthalate,
the dry heat shrinkage percentage of the carcass cords before subjected to the vulcanizing process is 1 to 3% at 180 degrees C., and
the Mooney viscosity of the raw topping rubber is 35 to 70 (ML1+4, 130 deg. C.).
In the present invention, during building and vulcanizing the raw tire, the core mold is used instead of the conventional expandable tire building drum and inflatable bladder. Accordingly, the inner liner rubber is not pressed against the carcass cords. Therefore, it becomes possible to decrease the thickness of the inner liner.
Even so, if the carcass cords are shrunken during vulcanization, in the tread portion and sidewall portions, the carcass cords move toward the inner liner and the inner liner penetrates between the carcass cords. As a result, the inner surface of the finished tire is liable to undulate along the surfaces of the carcass cords because of the thin inner liner. In the finished tire, if the inner liner is thin and undulated, cracks are liable to occur in the undulated area during use.
In the present invention, therefore, the carcass cords having a very small heat shrinkage percentage is used. As a result, the movement of the carcass cords toward the core mold due to heat shrinkage during vulcanization can be avoided. Further, owing to the specifically limited Mooney viscosity value, the raw topping rubber during vulcanization becomes hard to flow, and thereby, the inner liner rubber becomes hard to penetrate between the carcass cords.
Thus, even if the thickness of the inner liner is reduced, the undulation and resultant cracks can be effectively prevented, and the durability can be improved. Further, the topping rubber and the inner liner rubber can maintain their required thicknesses, therefore the problems with the exposure of the carcass cords, and the deterioration in the air sealing effect and the tire durability can be solved.
In the present invention, further, the low-cost polyethylene terephthalate or polyethylene naphthalate cords are used as the carcass cords, and further it is not necessary to use high-cost electron beam irradiation to reduce the flow of topping rubber, therefore, the production cost can be reduced.
Taking a passenger radial tire as an example, embodiments of the present invention will now be described in detail in conjunction with the accompanying drawings.
As shown in
The carcass 6 is composed of at least one ply 6A (in this example only one ply 6A) of carcass cords 11 arranged radially at an angle of 75 to 90 degrees with respect to the tire equator C, and extending between the bead portions 4 through the tread portion 2 and the sidewall portions 3, and the ply edges 6e are respectively terminated in the bead portion 4 without being turned back. In the or each carcass ply 6A, the both sides of the array 12 of the carcass cords 11 are covered with topping rubber 13.
The bead core 5 in this example is composed of an axially inner bead core 5A and an axially outer bead core 5B and the edge 6e of the carcass ply 6A is secured therebetween.
The axially inner bead core 5A and axially outer bead core 5B are each formed by compactly spirally winding a bead wire 5c, abutting on the axial inner surface 6i and axial outer surface 6o of the carcass ply, respectively.
Preferably used as the bead wire 5c is a steel cord made of high strength steel filaments twisted together.
The belt 7 is composed of at least two plies (in this embodiment only two cross plies 7A and 7B) of belt cords laid at an angle of from 10 to 40 degrees with respect to the tire equator C. In this embodiment, steel cords are used as the belt cords. But, it is also possible to use high modulus organic fiber cords, e.g. aramid, rayon and the like as required.
The inner liner 9 is disposed on the inside of the carcass 6 so as to cover the substantially entirety of the inner surface 10 of the tire. The inner liner 9 is made of air impermeable butyl rubber for example, containing at least 50 parts by weight of halogenated butyl rubber with respect to 100 parts by weight rubber.
In the bead portion 4, a bead apex 8 made of hard rubber and a chafer rubber 14 are disposed.
The bead apex 8 comprises an inner apex rubber 8i disposed on the axial inner surface 5Ai of the axially inner bead core 5A, and an outer apex rubber 8o disposed on the axially outer surface 5Bo of the axially outer bead core 5B. Each apex rubber 8i,8o extends radially outwardly beyond the radially outer end of the bead core 5A,5B and tapers to its radially outer end. Such apex rubber 8i and 8o increases the bending rigidity of the bead portion 4 and helps to improve the steering stability.
The chafer rubber 14 comprises
In order to manufacture the above described tire 1, a raw tire 1L is built on a core mold 16 as shown in
In this embodiment, the core mold 16 is provided with
The core mold 16 is a sprit mold made up of a plurality of pieces which are for example divided in the circumferential direction. The core mold 16 is made of a metal material, e.g. duralumin or the like which can endure heat and pressure during vulcanization.
Here the “5% pressure state” is such that the tire mounted on a standard wheel rim is once inflated to the standard pressure with no tire load, and then the pressure is decreased down to 5% of the standard pressure.
The standard wheel rim is a wheel rim officially approved or recommended for the tire by standards organizations, i.e. JATMA (Japan and Asia), T&RA (North America), ETRTO (Europe), TRAA (Australia), STRO (Scandinavia), ALAPA (Latin America), ITTAC (India) and the like which are effective in the area where the tire is manufactured, sold or used. The standard pressure and the standard tire load are the maximum air pressure and the maximum tire load for the tire specified by the same organization in the Air-pressure/Maximum-load Table or similar list. For example, the standard wheel rim is the “standard rim” specified in JATMA, the “Measuring Rim” in ETRTO, the “Design Rim” in TRA or the like. The standard pressure is the “maximum air pressure” in JATMA, the “Inflation Pressure” in ETRTO, the maximum pressure given in the “Tire Load Limits at various cold Inflation Pressures” table in TRA or the like. The standard load is the “maximum load capacity” in JATMA, the “Load capacity” in ETRTO, the maximum value given in the above-mentioned table in TRA or the like.
During building and vulcanizing the tire, the core mold does not expand differently from the bladder and tire building drum, therefore, the inner surface 10 of the tire can be supported steady with an even pressure distribution, and the thickness variations and the carcass cords' dislocation can be avoided.
Further, the expansion of the raw tire during building and the stretch of the raw tire during vulcanization are decreased or become almost zero, therefore, the carcass cords 11 are prevented from penetrating into the inner liner rubber 9. Thus, the decrease in the covering thickness of the topping rubber and inner liner rubber can be prevented. Accordingly, the exposure of the carcass cords, and the deterioration in the air sealing effect and the tire durability can be avoided.
The process for building the raw tire comprises
making the raw carcass ply 6L by rubberizing parallel carcass cords 11 with raw topping rubber 13L (hereinafter, the “raw carcass ply making step”), and
applying raw tire components including the raw carcass ply 6L onto the circumference surface 16s of the core mold 16 (hereinafter, the “applying step”).
Here, the term “raw” means conditions not completely vulcanized. Thus, so called semivulcanized condition is included.
In the raw carcass ply making step, the both sides of the array 12 of the carcass cords 11 are covered with the raw topping rubber 13L, and the raw carcass ply 6L is made.
For example, the raw topping rubber 13 is extruded from a twin-screw continuous-kneading extruder as two strips. The array 12 is sandwiched between the two strips and rolled. The boundary between the rolled two strips is substantially positioned at the center line of the array 12 of the carcass cords 11.
The carcass cords 11 are made from polyethylene terephthalate or polyethylene naphthalate, and
The dry heat shrinkage percentage can be set in the above range by changing the material (polyethylene terephthalate or polyethylene naphthalate), the twist structure of the cord, the conditions of dipping treatment for the cord and the like.
As specified in the Japanese Industrial standard JIS L1017, the dry heat shrinkage percentage is given by the ratio (y/x) in % of the shrinkage y of the cord when the cord with no load is subjected to a temperature of 180 deg. C. for 30 minutes to the original length x of the cord.
If the dry heat shrinkage percentage is more than 3%, then due to the heat shrinkage during vulcanization, the carcass cords 11 thrust into the inner liner 9, therefore, it becomes difficult to maintain the required minimum covering thickness. In addition, polyethylene terephthalate and polyethylene naphthalate are low-cost in comparison with aramid, therefore, the increase in the production cost can be avoided.
The Mooney viscosity of the raw topping rubber 13L is set in a range of not less than 35 (ML1+4, 130 deg. C.), preferably not less than 36 (ML1+4, 130 deg. C.), more preferably not less than 37 (ML1+4, 130 deg. C.), but not more than 70 (ML1+4, 130 deg. C.), preferably not more than 65 (ML1+4, 130 deg. C.). Namely, the value of the Mooney viscosity is larger than the values of the conventional raw topping rubber.
The Mooney viscosity can be set in the above range by changing the conditions for kneading the rubber, the blending quantities of additives. e.g. carbon black and the like,
The Mooney viscosity is measured according to Mooney viscosity test specified in JIS K6300 “Rubber, unvulcanized—Physical property” wherein the unvulcanized rubber is preheated at 130 degrees C. for one minute and an L-shaped rotor put therein is rotated for four minutes, then the Mooney viscosity is measured.
The rubber flow of such raw topping rubber 13L during vulcanization becomes less in comparison with usually used raw topping rubber. Accordingly, the plasticized inner liner rubber is prevented from flowing out between the carcass cords 11, and the thinning of the inner liner is prevented. Therefore, even if the thickness of the inner liner is decreased to the required minimum value, the minimum value can be maintained till after the vulcanization. In addition, such raw topping rubber 13L eliminates the need for electron beam irradiation process often employed to lessen the flow of raw topping rubber. Thus, it is possible to save the plant cost and production cost.
If the Mooney viscosity of the raw topping rubber 13L is less than 35 (ML1+4, 130 deg. C.), it becomes difficult to effectively reduce the rubber flow. If the Mooney viscosity is more than 70 (ML1+4, 130 deg. C.), during coating the carcass cords 11 with the raw topping rubber 13L, the heat generation increases, and degradation of the rubber occurs.
If the minimum covering thickness W1 of the raw topping rubber 13L from the carcass cords 11 is too small, there is a possibility that the plasticized inner liner rubber tends to flow out between the carcass cords 11, and the exposure of the carcass cords can not fully prevented. If the minimum covering thickness W1 is too large, then the rubber flow becomes insufficient, and defective molding is liable to occur. Therefore, as shown in
In the applying step, as shown in
First, the base part 14a of the chafer rubber 14 and the inner liner 9 are applied to the circumference surface 16s of the core mold 16. Then, the inner apex rubber 8i is applied to the axially outside thereof. More specifically, the base part 14a of the chafer rubber 14 is wound around the flange surface 16f of the core mold 16.
The inner liner 9 is formed by circumferentially winding a rubber tape (not shown) on the circumference surface 16s of the core mold 16 a large number of times with no gap between the windings. The rubber tape is made of unvulcanized rubber and has a width of about 5 to 35 mm and a thickness of about 0.5 to 2.0 mm. In view of the weight reduction, the thickness of the formed inner liner 9 is preferably less than 1.0 mm, more preferably 0.7 mm.
Next, the axially inner bead core 5A is formed axially outside the inner apex rubber 8i. Then, the raw carcass ply 6L is applied to the outside of the axially inner bead core 5A and inner liner 9.
The axially inner bead core 5A is formed by compactly spirally winding one bead wire 5c, starting from the radially outside of the base part 14a of the chafer rubber 14 toward the radially outside.
If the dimension L1 of the axially inner bead core 5A measured radially along the raw carcass ply 6L is too small, it is difficult to secure the carcass ply. Therefore, the dimension L1 is preferably not less than 8 mm, more preferably not less than 10 mm. If the dimension L1 is too large, the weight of the tire is unfavorably increased. From this standpoint, the dimension L1 is preferably not more than 25 mm, more preferably not more than 20 mm.
In this embodiment as shown in
Each strip 6P has a substantially constant width and extends from one of the bead cores to the other. Therefore, in the tread portion and sidewall portions, the edges of the strips 6P are butted. But, in the bead portions, the adjacent edges are partly overlapped with each other to absorb the difference in the circumferential length.
On the axially outside of the raw carcass ply 6L, as shown in
Similarly to the axially inner bead core 5A, the axially outer bead core 5B is formed by compactly spirally winding one bead wire 5c, starting from the base part 14a of the chafer rubber 14 toward the radially outside, along the axially outer surface of the raw carcass ply 6L.
The outer apex rubber 8o is disposed on the axially outside thereof.
Further, the axially outer part 14b is disposed on the axially outside thereof, and the radially inner edge of the axially outer part 14b is connected to the base part 14a.
Further, the sidewall rubber 3G, the belt 7, the tread rubber 2G and the like are applied.
Thereby, the raw tire 1L is formed on the core mold 16.
In the vulcanizing process, as shown in
Passenger car radial tires of size 195/65R15 having the structure shown in
In the manufacturing method using the core mold, the narrow-width cut strip 6P for forming the carcass ply had a width of 20 mm, and in the strip, twenty carcass cords were embedded along the length thereof in parallel with each other.
As to the carcass cords,
As to the topping rubber for the carcass cords, compositions shown in Table 1 were used.
The tires were tested for the durability. In the test, the tire mounted on a standard rim (size: 15X6JJ) and inflated to 200 kPa was run for 3000 km at a speed of 80 km/h under a tire load of 7 kN by the use of a tire test drum of 1.7 m diameter. Thereafter, the inner surface of the tire was checked for the number of cracks. The test results are indicated in Table 2 by index based on comparative tire Ref.1 being 100. The larger the value, the better the durability.
Through the test, it was confirmed that the manufacturing method according to the present invention can produce a pneumatic tire having the improved durability even if the thickness of the inner liner is reduced.
Number | Date | Country | Kind |
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2011-018745 | Jan 2011 | JP | national |