JP2011161678A - Bead core holder - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve uniformity by suppressing displacement or torsion of a bead core when setting the bead core. <P>SOLUTION: A bead core holder is equipped with a holding ring for holding the bead core with a bead apex rubber. The holding ring includes a seat surface for seating the inner peripheral surface of the bead core, a lower side surface for receiving the outside surface of the bead core, and an upper side surface which is continued to the lower side surface through an inclined surface and parallel to the lower side surface. The height H1 from the seat surface to the outer end of the lower side surface is made to be 20-70% of the height H of the bead core, the angle θ of the inclined surface is made to be 30-60°, and the distance L in the axial center direction between the lower side surface and the upper side surface is made to be 3.0 mm or more. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a bead core holder for setting a bead core on a side surface of a cylindrical drum around which a carcass ply is wound on an outer peripheral surface via the wound carcass ply.

  As the bead core holder a used in the raw tire forming process, those described in Patent Documents 1 and 2 are known. As shown in FIGS. 6A and 6B, the bead core holder a has a bead core c on the inner peripheral edge of the disk-shaped side wall a1 having a side surface a1s that receives the side surface of the bead core c with the bead apex rubber b. A core support portion a2 having a seating surface a2s on which the inner peripheral surface of the core is seated is formed as a ring body having an L-shaped cross section projecting in the axial direction.

  As shown in FIG. 7, this bead core holder a is a raw tire using a molding former in which a drum sub-portion e having a turn-up bladder (not shown) is arranged on both sides of a cylindrical drum d capable of reducing the diameter. Used in the forming process.

  Specifically, on the outer peripheral surface of the drum d, a sheet-like carcass ply f1 is wound with both side portions protruding from both ends of the drum d to form a cylindrical carcass tube f. The protruding portion fe of the carcass tube f is narrowed to a small diameter by using a finger g that can be freely opened and closed. Thereafter, the bead core h with bead apex rubber held by the bead core holder a is set on the side surface of the drum d via the narrowed carcass ply f1, and the turn-up bladder is expanded, The protruding portion fe is folded around the bead core h with bead apex rubber.

  When turning up by the turn-up bladder, as shown in FIG. 8, the upper end portion of the bead apex rubber i in the set bead core h with bead apex rubber may be laid down along the outer peripheral surface of the drum d. Done. However, in the conventional bead core h with bead apex rubber, the inner peripheral surface of the bead apex rubber i is formed to have substantially the same width as the outer peripheral surface of the bead core h as shown in FIG. Therefore, the bonding area between the bead apex rubber i and the bead core h is insufficient, and when the bead apex rubber i is laid down, the bead apex rubber i causes separation j from the bead core h, resulting in poor formation of a raw tire. There's a problem. In particular, in recent years, the bead core h is made narrower (lighter) by improving the forming material and forming method of the bead core. However, since this narrowing leads to a decrease in the bonding area, the peeling is more likely to occur. Become.

  Therefore, as shown in FIG. 9B, it is desired to provide a bead apex rubber i with an overhanging portion i1 that adheres to a part of the side surface of the bead core h.

  However, when the bead apex rubber i provided with the overhanging portion i1 is held by the conventional bead core holder a, the overhanging portion i1 comes into contact with the side surface a1s of the bead core holder a, so that the bead apex rubber i is seated. Not only does it become unstable and it causes the bead core to fall during transfer, but also causes a misalignment and twisting of the bead core during setting, causing the carcass cord path between the bead cores to vary and lowering the tire uniformity. appear.

JP 2001-30371 A JP 2001-341111 A

  Therefore, the present invention can stably hold the bead core with the bead apex rubber at an accurate position even when the bead apex rubber is provided with an overhang portion to increase the adhesion area with the bead core. An object of the present invention is to provide a bead core holder that can suppress not only the fall but also the positional deviation and twist of the bead core at the time of setting, thereby suppressing a decrease in tire uniformity.

In order to solve the above problems, the invention of claim 1 of the present application can hold a bead core with a bead apex rubber, and the bead core with the bead apex rubber is wound around a sheet-like carcass ply on an outer peripheral surface. A bead core holder that is set on the side surface of a cylindrical drum via the wound carcass ply,
A support member that is held movably in the axial direction toward the side surface of the drum, and a holding ring that holds a bead core with a bead apex rubber attached to the support member,
The retaining ring is
A seating surface for seating the radially inner circumferential surface of the bead core;
A radially inner lower surface that receives an axially outer surface of the bead core;
A radially outer end of the lower side surface, which is connected via an inclined surface inclined axially outward toward the radially outer side, and an upper side surface of the radially outer side parallel to the lower side surface;
Moreover, the radial height H1 from the seating surface to the radially outer end of the lower side surface is 20 to 70% of the radial height H of the bead core, and the angle θ of the inclined surface with respect to the axial line is 30. The distance L in the axial direction between the lower side surface and the upper side surface is set to 3.0 mm or more.

  In the invention of claim 2, the holding ring is composed of a plurality of ring pieces arranged at intervals in the tire circumferential direction, and the circumferential distance K between adjacent ring pieces in the circumferential direction is the seating surface. It is characterized by being in the range of 65 to 75 mm at the position of.

  As described above, according to the present invention, the side surface of the holding ring is formed as a step surface having a lower surface, an inclined surface, and an upper surface, and the height of the lower surface, the angle of the inclined surface, the lower surface and the upper surface, The distance in the axial direction is specified. Therefore, even when the bead apex rubber is provided with an overhang to increase the adhesion area with the bead core, it is possible to avoid contact between the retaining ring and the bead apex rubber, and the bead core is securely attached to the lower surface of the retaining ring. It can be held in a stable and accurate position. Therefore, not only the fall of the bead core during the transfer, but also the positional deviation or twist of the bead core during setting, and the deterioration of the tire uniformity can be suppressed.

It is a side view which shows an example of the raw tire shaping | molding apparatus using the bead core holder of this invention. It is a front view of a bead core holder. It is an expanded sectional view of a bead core holder. (A) is sectional drawing which shows a bead core with a bead apex rubber, (B) is sectional drawing which expands and shows an overhang | projection part. It is an expansion perspective view which exaggerates and shows the joined part of bead apex rubber. (A), (B) is the perspective view which shows the conventional bead core holder, and a partial expanded sectional view. It is explanatory drawing of a raw tire formation process. It is sectional drawing explaining the lying down of the bead apex rubber in a green tire formation process. (A), (B) is sectional drawing which shows the bead core with a bead apex rubber.

Hereinafter, embodiments of the present invention will be described in detail.
FIG. 1 is a side view showing an example of a raw tire molding apparatus 2 using a bead core holder 1 of the present invention.

  In FIG. 1, a raw tire molding apparatus 2 includes a molding former 5 in which a drum sub-portion 4 having a turn-up bladder is arranged on both sides of a cylindrical drum 3 that can be reduced in diameter, and a bead apex rubber on a side surface of the drum 3. A bead core setter 8 having a bead core holder 1 for setting a bead core 7 with 6 is provided.

  As the molding former 5, a conventional molding former having a well-known structure can be adopted.

  The bead core setter 8 includes bead core setters 8R and 8L arranged on one side and the other side of the molding former 5, and the bead core setter 8R on one side is supported by the support shaft portion 9 of the molding former 5. . In this example, the bead core setter 8R on one side includes, for example, a cylindrical support body 11 that is slidably held by a support cylinder 10 that is externally inserted into the support shaft portion 9, and the axial center of the support body 11 is provided. The bead core holder 1 is attached to the inner end in the direction.

  The other-side bead core setter 8L includes, for example, a cylindrical support 14 that is attached to a movable table 13 that is movable in the axial direction along a guide rail 12 laid on the floor surface or the like. The bead core holder 1 is attached to the inner end in the axial direction. A support cylinder 15 is concentrically fixed to the support body 14, and a known finger 16 is held on the support cylinder 15 so as to be movable relative to the support body 14 in the axial direction. Note that the finger 16 is held on the support cylinder 10 so as to be relatively movable in the axial direction with respect to the support 11 also in the bead core setter 8R on one side. As is well known, the finger 16 can open and close between a substantially standing state with a forward inclination about a fulcrum P and a substantially horizontal tilted state, and the drum 16 in a carcass ply wound on the outer peripheral surface of the drum 3 is provided. The part protruding from both ends of 3 is narrowed down to a small diameter.

  Next, as shown in FIGS. 2 and 3, the bead core holder 1 includes a support member 20 that is movable in the axial direction toward the side surface of the drum 3 by being attached to the support bodies 11 and 14, and the support member 20. A holding ring 21 is provided that is attached to the member 20 and holds the bead core 7 with the bead apex rubber 6.

  The bead core 7 is formed in a rectangular cross section in which bead wires are wound in multiple stages and multiple rows in the circumferential direction. In this example, the bead apex rubber 6 includes a base 6a having a substantially triangular cross section rising radially outward from the outer peripheral surface SU of the bead core 7 and an axially outer side of the bead core 7, as shown in FIG. A thing provided with the overhang | projection part 6b overhang | projected from the side surface So and adhere | attached on the upper part of the said outer side surface So is used. As shown in an enlarged view in FIG. 4B, the bead apex rubber 6 uses, for example, a rubber member G having a triangular cross section having a base wider than the width of the bead core 7, and a portion Ga protruding from the bead core 7. It is formed by rolling down. Accordingly, the adhesion height Ta to the outer surface So by the projecting portion 6b is as small as 30% or less of the radial height H of the bead core 7, and the projecting amount Tb from the outer surface So of the projecting portion 6b is the above-mentioned. It is smaller than the bonding height Ta.

  Next, the support member 20 is formed of an annular plate concentric with the drum 3 in this example. Further, in this example, the holding ring 21 is formed of a plurality of ring pieces 21 </ b> A arranged at intervals in the tire circumferential direction. Each ring piece 21A has a core support portion 22 having a seating surface 22S on which the inner peripheral surface SL of the bead core 7 is seated, and a radially outer side from the core support portion 22 as shown in an enlarged view in FIG. And a side wall portion 23 standing up. The side wall portion 23 includes a radially inner lower side surface 23S1 that receives the axially outer side surface So of the bead core 7, and a radially outer end of the lower side surface 23S1 that is axially outward toward the radially outer side. A radially outward upper side surface 23S3 that is continuous through the inclined surface 23S2 that is inclined in the direction and parallel to the lower side surface 23S1 is formed.

  In the ring piece 21A, the radial height H1 from the seating surface 22S to the radially outer end of the lower side surface 23S1 is 20 to 70% of the radial height H of the bead core 7, and the inclined surface The angle θ of 23S2 with respect to the axial direction line is 30 to 60 °, and the axial distance L between the lower side surface 23S1 and the upper side surface 23S3 is 3.0 mm or more.

  Thus, since the side surface of the ring piece 21A is a stepped surface composed of the lower side surface 23S1, the inclined surface 23S2, and the upper side surface 23S3, even when the bead apex rubber 6 has the protruding portion 6b, the retaining ring 21 and the bead Contact with the apex rubber 6 can be avoided, and the bead core 7 can be reliably held in contact with the lower surface 23S1 of the holding ring 21 with certainty. Therefore, not only the fall of the bead core during transfer, but also the misalignment and twist of the bead core during setting, and the deterioration of the tire uniformity due to it can be suppressed.

  Here, when the height H1 exceeds 70% of the height H of the bead core 7, the distance L is less than 3.0 mm, and the angle θ exceeds 60 °, the holding ring 21 and the overhanging portion 6b The possibility of contact increases, making it difficult to reliably hold the bead core 7 in contact with the lower side surface 23S1 and stably hold it at an accurate position. On the other hand, if the height H1 is less than 20% of the height H of the bead core 7, the contact between the bead core 7 and the lower side surface 23S1 becomes insufficient and cannot be stably held at an accurate position. On the other hand, if the angle θ is less than 30 °, there is a risk of erroneous mounting such that the bead core 7 is caught by the inclined surface 23S2 and held. From such a viewpoint, the upper limit of the height H1 is preferably 60% or less and the lower limit is preferably 40% or more, and the upper limit of the angle θ is preferably 50 ° or less and the lower limit is preferably 40% or more. Further, even if the distance L is too large, the uniformity and the like are adversely affected. Therefore, the upper limit of the distance L is preferably 10 mm or less.

  The bead apex rubber 6 is formed by abutting and press-contacting both longitudinal end surfaces Ge of a rubber member G extruded from a rubber extruder. At this time, as shown in an exaggerated manner in FIG. In part J, the rubber tends to thicken. And this thick part Ja contacts the said inclined surface 23S2 and upper side surface 23S3, and there exists a possibility that the position shift and twist of a bead core may be caused. Therefore, in this example, the holding ring 21 is formed by a plurality of ring pieces 21A arranged at intervals in the tire circumferential direction, and the contact is achieved by letting the thick portion Ja through the gap D. Can be prevented. For that purpose, it is preferable that the circumferential distance K between the ring pieces 21A, 21A adjacent in the circumferential direction is in a range of 65 to 75 mm at the position of the seating surface 22S. It will be difficult to escape. On the other hand, if the distance K exceeds 75 mm, the bead core 7 becomes polygonal, which tends to impair the uniformity.

  In the bead core holder 1, the support member 20 is also formed of a plurality of support member pieces divided in the circumferential direction, and ring pieces 21A attached to the support member pieces are integrated with the support member pieces in the radial direction. The retaining ring 21 can be expanded and contracted.

  As mentioned above, although especially preferable embodiment of this invention was explained in full detail, this invention is not limited to embodiment of illustration, It can deform | transform and implement in a various aspect.

  In order to confirm the effect of the present invention, a tire for a passenger car (tire size 225 / 55R17) is formed using a raw tire molding apparatus employing a bead core holder shown in FIG. The difference in tire uniformity was measured. The conditions are substantially the same except for the bead core holder.

  As a bead core with a bead apex rubber (described as a core assembly in the table), type A shown in FIG. 9A and type B shown in FIG. 9B are used. The bead core size is the same (width (9.0 mm) x height H (6.0) mm). The bead apex rubber is different only in the presence or absence of the overhanging portion. When the overhanging portion is present, the adhesion height Ta is 5.0 mm and the overhanging amount Tb is 3.0 mm.

(1) Defect rate:
The occurrence rate of peeling of the bead apex rubber from the bead core that occurred when the upper end portion of the bead apex rubber was laid down along the outer peripheral surface of the drum during the formation of the green tire was measured for a production number of 10,000.

(2) Uniformity:
The tire uniformity tester was used and RFV was measured according to JASO C607: 2000 “Uniformity test method for automobile tires”, and the result was expressed as an index with Conventional Example 1 as 100. The smaller the index, the better the uniformity. Measurement conditions were a rim (17 inches), tire rotation speed (60 rpm), air pressure (200 kPa), and longitudinal load (5.04 kN).

  In addition, the height H1 (* 1) of the lower surface in the table is indicated by a ratio (H1 / H) to the height H of the bead core. As shown in the table, the embodiment can suppress the positional deviation and twist of the bead core at the time of setting, and it can be confirmed that the uniformity of the tire is improved by making the carcass cord path uniform in the circumferential direction.

1 Bead core holder 3 Drum 6 Bead apex rubber 7 Bead core 17 Carcass ply 20 Support member 21 Holding ring 21A Ring piece 22S Seating surface 23S1 Lower side surface 23S2 Inclined surface 23S3 Upper side surface SL Inner circumferential surface So Outer side surface

Claims (2)

The bead core with the bead apex rubber can be held, and the bead core with the bead apex rubber is held on the side surface of the cylindrical drum on which the sheet-like carcass ply is wound on the outer peripheral surface. A bead core holder that is set via
A support member that is held movably in the axial direction toward the side surface of the drum, and a holding ring that holds a bead core with a bead apex rubber attached to the support member,
The retaining ring is
A seating surface for seating the radially inner circumferential surface of the bead core;
A radially inner lower surface that receives an axially outer surface of the bead core;
A radially outer end of the lower side surface connected via an inclined surface inclined axially outward toward the radially outer side, and a radially outer upper side surface parallel to the lower side surface,
Moreover, the radial height H1 from the seating surface to the radially outer end of the lower side surface is 20 to 70% of the radial height H of the bead core, and the angle θ of the inclined surface with respect to the axial line is 30. A bead core holder, characterized in that the distance L in the axial direction between the lower side surface and the upper side surface is set to 3.0 mm or more.   The holding ring is composed of a plurality of ring pieces arranged at intervals in the tire circumferential direction, and a circumferential distance K between adjacent ring pieces in the circumferential direction is in a range of 65 to 75 mm at the position of the seating surface. The bead core holder according to claim 1, wherein

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