FR2781723A1 - RADIAL TIRE SADDLE - Google Patents

Abstract

The invention concerns a tyre for heavy vehicles, to be mounted on a rim J whereof the seats are inclined at an angle ranging between 0 DEG and 16 DEG relatively to the axis of rotation and comprising a radial body armour (10) anchored in each bead. The invention is characterised in that said tyre is vulcanised by the action of the vulcanising fluid directly on the tyre blank inner walls, the seat (20) of each bead, consisting, axially outside a first conical portion (21), axially inside a second conical portion (22), both said conical portions being axially assembled by a circumferentially continuous rubber protuberance (23).

Description

The invention relates to a tire intended to equip heavy vehicles.

  and to be mounted on a rim whose seats are inclined relative to the axis of rotation by an angle between 0 and 16, that is to say rims with flat seats as well as rims with inclined seats to 5 and / or 15, and more particularly a tire known as without

air chamber.

  In the generally used techniques for vulcanizing raw tire blanks, said blank is shaped and pressed against the vulcanization mold by means of an inflatable rubber bladder capable of transmitting heat, a bladder which can be thick and commonly called bag of

  vulcanization or so thin and then called vulcanization membrane.

  The disadvantage of these techniques is due, on the one hand to the device or press necessary for its production and, on the other hand to the nature of the inflation bladder itself which, sensitive to multiple deteriorations, must be replaced after a certain number of baking operations carried out, a replacement operation on the one hand costly and generating on the other hand down time of the vulcanization press which have repercussions on the cost price of the tire, all the more so since the bladder of rubber does not allow the fastest vulcanization that would be desired. In addition, possible heterogeneities of the bladder are found, vulcanization finished, in the finished tire and directly affect production. During the shaping process, for example, the places with the smallest thickness of the inflatable bladder expand more strongly than the others and cause excessive expansion of the tire blank at the corresponding places. It may also be mentioned that the inflatable bladder has on its outer surface a series of grooves intended for the evacuation of the air trapped between the tire blank and the bladder. During the vulcanization process, said grooves form on the inner surface of the tire ribs which can cause deformations of the inner layers of the carcass reinforcement, In addition, and more particularly in the case of the use of a membrane , many folds exist on said membrane; and the

  lack of uniformity thus created affects the tire itself.

  To overcome the above drawbacks, we have been led, by renouncing the use of an inflation and vulcanization bladder, to cause the vulcanization fluid to act directly on the interior wall of the tire blank, while we just press in the axial direction and by means of circumferential plates called clamping the heels or beads of the blank against the

  corresponding surfaces of the vulcanization mold.

  In the vulcanization devices used previously without an inflation bladder, the drawbacks of the use of clamping plates or rings are firstly mechanical, the installation of such plates after closing the press requires high mechanical technicality, and secondly of a thermal order, the part of the bead axially compressed being withdrawn from the action of the heating fluid, which obviously causes a variation in vulcanization temperature in the bead itself and therefore creates a significant difference in vulcanization, o a heterogeneity of quality of mixtures and consequently a

  bead endurance greatly reduced.

  Whether during the vulcanization operation, or after mounting the tire on its rim, it is essential to establish a perfect seal in the region of the beads between the elements either of the blank or of the tire and the elements

  corresponding metal either from the vulcanization mold or from the mounting rim.

  Indeed, on the one hand the penetration of the vulcanization fluid between the external wall of the pncumnatic and the mold would lead to defective tires, and on the other hand the sealing connection during mounting on rim and inflation would be made impossible because the absence of a gum point, an inherent absence in the choice of cooking without a bladder

and without clamping rings.

  The object of the invention is to remedy the combined drawbacks described above.

  above. The tire for "heavy" vehicles, according to the invention, intended to be mounted on a rim whose seats are inclined at an angle which may be between 0 and 16 relative to the axis of rotation and comprising a carcass reinforcement radial anchored in each bead, is characterized in that, said tire being vulcanized by the action of the vulcanizing fluid directly on the interior walls of the tire blank and said walls having radial ends at the base of the beads, the seat of each bead is composed, axially on the outside by a first frustoconical portion, the generatrix of said portion making with the axis of rotation an angle a between 5 and 30 and having an axial width LI between 0.05 and 0, 12 times the height on rim of said tire, the edge of said first frustoconical portion being axially provided with a rubber protuberance, circumferential continuous ement, height h between 0.5 mm and 3 mm, width I between 0.25 and 0.60 times the width LI, said protuberance ensuring the axial junction with the axially outer end of a second frustoconical portion , whose generator makes with the axis of rotation an angle X included in

the interval (-5, +5).

  The seat of the bead thus described corresponds to the shape obtained by molding on the metal part of the vulcanization mold, and said seat does not have the grainy appearance of the inner wall of the tire, particle size due to the absence of contact, during the vulcanization, between the rubber of said wall and either

  vulcanization bladder rubber ct / or mold metal.

  If the term bead diameter is understood to mean the diameter measured at the intersection of the seat generatrix and the axially outer and substantially vertical wall of said bead, and if the rim diameter is given the same definition at 150, it it is advantageous that the bead diameter is between 0.995 and 0.998 times the

rim diameter.

  The height h of the protuberance is measured on a perpendicular to the frustoconical generator of the first portion of bead seat. The axial width of the second frustoconical (or cylindrical) portion of the bead seat is variable and depends on the total width of the bead seat, which can be very variable in

  function of the interior architecture of the bead.

  The invention will be better understood using the drawing appended to the description

  illustrating non-limiting examples of execution, drawing where we can see: - in FIG. 1, the meridian profile of the seat of a tire bead 385/65 R 22.5, in accordance with the invention, FIG. 2 a first bead according to the invention, - in FIG. 3 a second bead according to the invention,

  - In Figure 4 a third bead according to the invention.

  The meridian contour (FIG. 1 in dotted lines) of the rim J for mounting the tire according to the invention, said rim having rim seats inclined at + 1, is, according to international standards, mainly formed by a flange ( 1) rim, circular with radius RI, constant whatever the width A and the nominal diameter Dj of the rim, flange joined to the inclined seat (2) by a circular portion of radius R2, also constant. The inclined seat (2) extends over an axial distance P of which, according to ETRTO standards, the minimum value varies according to the rim dimensions, between 25 and 36 mmin. On the tire mounting side, the seat (2) is joined to the mounting groove (3) by a succession of two circular arcs of radii R3 and R4 s respectively, equal to 8 and 16 mm. The groove (3) has a minimum depth H as well as a minimum width to be observed for correct fitting of the tire,

  this depth and this width being standardized.

  If we consider the side opposite the mounting side of the tire, the flange

  rim (1) and seat (2) are symmetrical to the flange (1) and to the seat (2) on the mounting side.

  On the other hand, the seat (2) is extended axially inside by a cylindrical part (not shown) of width such that the axial width of the rim and the axial width of its mounting groove are respected. This cylindrical part has, moreover, a

  diameter less than or equal to Dj - 22 mm, depending on the size of the rim.

  As for the meridian profile AB of the seat (20) of the tire bead, profile imparted by the profile of the seat of the corresponding metal part of the vulcanization mold and profile intended to come at least partially into contact with the rim seat, it is connected to the substantially vertical part (24) of the vulcanization mold by a rounded radius. Said seat (20) of axial width L is composed, axially on the outside, of a first frustoconical portion (21), the generatrix AC of said portion making with the axis of rotation an angle ca equal to 25 and having a axial width L1 equal to 0.07 times the height H of the tire on the rim (the height of the tire on the rim should be understood to mean the radial distance separating the point of the meridian profile of the carcass reinforcement furthest from the axis of rotation of the straight line parallel to the axis of rotation passing through the point of intersection of the frustoconical rim generator with the portion of the rim flange perpendicular to said axis of rotation). The axially inner edge CD of the first portion (21) is provided with a rubber protuberance (23), continues circumferentially and having, seen in meridian section, a section of quasi-triangular shape, with a height h equal to I18 mm and a base of axial width I equal to 0.5 times the width L1 of the first frustoconical portion (2 1) of bead. If the height h is less than 0.5 mm, the protuberance (23) is not fully effective, and if said height is greater than 3 mm, said protuberance under the effect of the tightening of the bead on the rim J lies down and also loses its effectiveness. Likewise, if the width 1 is less than 0.25 times the width L], the protuberance lies down, and if 1 is greater than 0.6 times the width LI, the assembly

  tire on its service rim becomes difficult.

  Said protuberance (23) provides the axial junction between the frustoconical portion (21) and a second frustoconical portion (22) of axial width L ,, equal to 0.3 times the width LI, in the example described, and whose generator BC makes an angle equal to 0 with the axis of rotation (a cylindrical generator being considered as a

  frustoconical generator at zero angle).

  The diameter DB of the bead is equal to 0.998 times the diameter Dj of the mounting rim J, which corresponds to sufficient tightening of the bead on its rim in view

avoid any rotation on the rim.

  FIG. 2 shows the bead B of a tire according to the invention, said tire being provided with a radial carcass reinforcement, composed in the example described of a single ply (10) of inextensible steel wire cables. Said carcass ply is anchored by winding to at least one rod (30), composed of several wires of rectangular section wound and wrapped in a layer (31) of rubber mix with high elasticity modulus. The axial position of the center of gravity of the cross section of the protuberance (23) is then substantially in line with the axially inner part of the rod (30). The anchoring is done by a rctoucement (11) around the layer (30). Between the carcass reinforcement (10) and its upturn (I 1), radially above the rod (30), is disposed a first rod stuffing (40) made of a rubbery mixture of generally high Shore A hardness, said first stuffing (40) being extended radially by a second packing (50) cn rubber mixture of Shore hardness lower than the previous one and the radially upper end of said packing (50) being substantially located at the maximum axial width of the tire. The structure of the bead according to the invention also comprises a reinforcing reinforcement (60), also formed of a single ply (60) of inextensible metallic steel cables parallel to each other in the ply and forming with the circumferential direction an angle of 22, said ply (60) being located axially outside the upturn (11) of the carcass ply (10) and separated from said upturn by a rubber mix profile (80), covering said upturn and the profile (50) . A layer of protective mixture (90) surrounds the axially outer face and the base of the bead, ensuring contact with the rim J. As can be seen in FIG. 2, the meridian profile of the axially inner wall of the bead (radially beyond B) is substantially the same in the vulcanized state as in the raw state, that is to say substantially circular, due to the absence on said face, during vulcanization, of a bladder of vulcanization or metal of axial clamping rings: this vulcanization without axial stress on the bead allows the conservation of the respective shapes and positions of the constituent elements of the tire, in particular the conservation of the internal shapes of said tire and the conservation of the positions of the reinforcements reinforcement, hence the absence of harmful prestressing caused

  by the shaping between the raw state and the vulcanized state of the bead.

  Figuire 3 relates to a bead architecture in accordance with the description of the

  application FR 97/14 409, not published to date, and in particular in the description

  corresponding to Figure 3 of said application. The "Heavyweight" tire, also of dimension 385/65 R 22.5 (FIG. 3), is intended to be mounted on a hollow base rim having rim seats inclined at 15, and comprises a tread joined to two beads by two flanks. A carcass reinforcement, composed of a single ply (10) of metallic steel cables, reinforces said tire, said carcass reinforcement having in each bead a meridian profile curved by going axially and radially from the outside to the inside for forming an axially inner edge located in an angle open axially and radially inward, one of the sides of which is parallel to the axis of rotation and of value at most equal to 25. Said meridian profile of the carcass ply (10) is formed by two arcs of a circle AiBl and BiC1, the arc B1C1 being extended by a line segment C1D1 making an angle of 10 with the axis of rotation. The carcass reinforcement portion (10) included in the bead is reinforced, on the one hand by an additional layer (6) radially exterior and axially interior composed of two plies (61) and (6,) of metallic cables in steel, and on the other hand by a second additional layer (7), said second layer being formed of two parts * of a first part (70), extending from point BI to a perpendicular to the axis of lowered rotation of point C1 of the meridian profile of the carcass reinforcement, and formed of a sheet of metallic steel cables, inextensible, and oriented circumferentially; and * axially inside from said point C1 of a second part (71) forged with a ply of metallic steel cables corrugated in the plane of the layer and of circumferential mean orientation. tablecloth of identical constitution to the tablecloth

forming the third part.

  The meridian profile of the tire bead seat (20) meets exactly the same criteria as those defined above, since we are in the presence of the same tire size. Said profile is composed, axially on the outside, of a first frustoconical portion (21) whose generatrix AC of said portion makes with the axis of rotation an angle ae equal to 25 and of axial width L1 the axially inner edge CD of said first portion (21) being provided with a protuberance (23) of rubber, circumferentially continuous, of the same shape in meridian section, said protuberance (23) ensuring the axial junction between the frustoconical portion (21) and a second frustoconical portion (22) of axial width L2, whose generatrix makes an angle equal to 0 with the axis of rotation. On the other hand, and unlike the first example described, the rounded portion which makes, radially beyond point B, the junction between the bead seat and the inner wall of the tire sidewall, has, due to the architecture particular of the bead, a radius of curvature of lower value, said radius not being able to be tangentially connected to the

portion (22).

  Figure 4 shows a variant bead according to the embodiment of Figure 2, and for which the use of baking without membrane combined with the special profile of the bead seat has a significant and certain advantage. The bead shown is such that the meridian profile of the radial carcass reinforcement (10) does not have an inflection point I (radially above the bead wire: FIG. 2), said profile having a line, lying between the point of greater axial width (not shown) of the reinforcement (10) and the point of tangency T to the anchor rod (30) (coated or not) continuously convex. The invention makes it possible to obtain a production yield and regularity

  impossible with the usual vulcanization processes.

Claims (2)

CLAIMS.   1 - Tire for "heavy" vehicles, intended to be mounted on a rim J, the seats of which are inclined at an angle between 0 and 16 relative to the axis of rotation and comprising a radial carcass reinforcement (10) anchored in each bead, is characterized in that, said tire being vulcanized by action of the vulcanizing fluid directly on the interior walls of the tire blank and said walls having radial ends at the base of the beads, the seat (20) of each bead is composed, axially outside by a first frustoconical portion (21), the generatrix AC of said portion (21) making an angle ca of between 5 and 30 with the axis of rotation and having an axial width L 1 between 0.05 and 0.12 times the height H on rim of said tire, the edge CD of said first frustoconical portion being axially provided with a protuberance (23) of rubber, continues circumferentially t, of height h between 0.5 mm and 3 mm, of width I between 0.25 and 0.60 times the width L 1, said protuberance (23) ensuring the axial junction with the axially outer end of a second frustoconical portion (22), whose generator BC makes an angle with the axis of rotation   included in the interval (-5, +5).   2 - A tire according to claim 1, characterized in that the diameter of the   bead DB is between 0.995 and 0.998 times the rim diameter Dj.