FR2969181A1 - Multi-strand metal cable for stiffening crown reinforcement of tire of e.g. mining vehicle, has single strand forming inner layer, and six strands forming outer layer, where each strand includes internal wires with specific diameter - Google Patents

Abstract

The cable (100) has a single strand forming an inner layer (CI), and six strands wound around the inner layer to form an outer layer (CE). Each cable strand includes three internal wires (12) forming an intermediate layer of the strand, where the diameter of each wire is greater than or equal to 0.15 mm and less than or equal to 0.45 mm. Eight external wires (13) are wound in a helix pattern around the intermediate layer of the strand, where the ratio of diameter of each strand in the inner layer to that of the outer layer is greater than or equal to 0.3 and less than or equal to 0.4.

Description

FIELD OF THE INVENTION [0001] The present invention relates to multistrand cables ("multistrand ropes") with high mechanical strength, usable in particular for the reinforcement of pneumatic tires for heavy industrial vehicles such as civil engineering vehicles of the mining type. It also relates to tires and reinforcements reinforcing these tires, and in particular the crown reinforcement also called "belts" of these tires, particularly the strengthening of tire belts for heavy industrial vehicles.

BACKGROUND [0003] A radial tire comprises, in known manner, a tread, two inextensible beads, two flanks connecting the beads to the tread, a carcass reinforcement and a belt circumferentially disposed between the carcass reinforcement and the body. tread. This belt consists of various plies (or "layers") of rubber reinforced or not by reinforcing elements ("reinforcements") such as cords or monofilaments, metal or textile type. The belt is generally made of several superimposed belt plies, sometimes called "working" or "crossed" plies, whose reinforcing cables, generally metallic, are arranged substantially parallel to each other inside. of a web, but crossed from one web to another, that is to say inclined, symmetrically or otherwise, with respect to the median circumferential plane. These crossed plies are generally supplemented by various other plies or layers of auxiliary rubber, of varying widths depending on the case, with or without metal reinforcements. In particular, the so-called "protection" plies responsible for protecting the rest of the belt from external aggressions, and in particular perforations, or "hooping" plies comprising reinforcements made of metal or not oriented substantially in the circumferential direction ( so-called "zero degree" plies), whether they are radially external or internal with respect to the crossed plies. Such a tire belt must satisfy in a known manner to different requirements, often contradictory, in particular: 2969181 -2 be the most rigid possible low deformation, because it contributes in a substantial way to stiffen the top of the tire; to have as low a hysteresis as possible, on the one hand to minimize heating during rolling of the inner zone of the crown and, on the other hand, to reduce the rolling resistance of the tire, which is synonymous with fuel economy; finally possess a high endurance, vis-à-vis in particular the separation phenomenon, cracking of the ends of the crossed plies in the shoulder area of the tire, known as the "cleavage", which requires in particular metal cables which reinforce the belt plies to exhibit high compressive fatigue resistance, all in a more or less corrosive atmosphere. For the reinforcement of the working lap belts of such tires above, two-layer multi-strand steel (Cl, CE) cables of strands are generally used, in which an outer layer (CE) of the cable is formed around the inner layer (Cl) of the cable, as described for example in the patents or patent applications US 5461850, US 5768874, US 6247514, US 6817395, US 6863103, US 7426821, US 2007/0144648, WO 2008 / 026271. As is well known to those skilled in the art, these strand cables must be impregnated as much as possible by the rubber in the tire belts they reinforce, so that this rubber penetrates into a maximum of 20 spaces. between the wires constituting the strands. If this penetration is insufficient, then empty channels remain along the strands, and corrosive agents, for example water, likely to penetrate the tires, for example as a result of cuts or other aggressions of the belt. pneumatic, run along these channels through said belt. The presence of this moisture plays an important role in causing corrosion and accelerating the fatigue processes (so-called "fatigue-corrosion" phenomena), compared to use in a dry atmosphere. [0008] All these phenomena of fatigue that are generally grouped under the generic term "fatigue-fretting-corrosion" are at the origin of a progressive degeneration of the mechanical properties of the cables and strands and may affect, for the most severe driving conditions, the service life of the latter. The constituent elementary strands of these multistrand cables, at least for some, however have the disadvantage that they are not penetrable to the core. This is particularly the case for multitoron construction cables (1 + 6) in which each strand consists of a cable with two layers of construction "3 + 9". By way of example, JP 08 109 585 discloses such a cable. As the outer layers of the strands are saturated, it is difficult to penetrate rubber compositions to the core of the strands and even to the core of the strand. It is for this reason that it has been proposed to desaturate the outer layers of the strands, using multitoron construction cables (1 + 6) in which each strand consists of a cable with two layers of construction " 3 + 8 ". JP 2009-52177 discloses such a cable. It is found that, despite a marked improvement in penetration, it is not yet perfect. Note that the construction (1 + 6) x (3 + 9) is deemed saturated and therefore impenetrable to the calendering mixture as recalled in JP 2001-011784. In this document, desaturation is achieved by deleting a strand. This approach, however, has the double disadvantage of reducing the breaking strength of the cable and increasing the structural instability of the assembly. SUMMARY OF THE INVENTION [0013] One of the objects of the present invention is to provide a multi-layer steel cable with two layers (Cl, CE) of strands, having excellent penetrability to the core of the strands and in the space between the strands of the outer layer (CE) of the cable and the inner layer (Cl) of the cable, without resorting to in situ scrubbing. This objective is achieved by a multi-strand metal cable with two layers (Cl, CE) strands, of construction "1 + 6", used in particular for the reinforcement of tires for industrial vehicles, comprising a single strand forming a layer 25 internal (Cl) cable, wherein six strands are wound, helically, in a pitch P3, to form an outer layer (CE) of the cable around the inner layer (Cl) of the cable, each strand consisting of a 3-layer construction cable "1 + 3 + 8", comprising: a wire of diameter d0 forming an inner layer (CO) of the strand; three wires of diameter d1 forming an intermediate layer (C1) of the strand, the three wires being wound in a pitch P1 around the inner layer (CO) of the strand, the diameter d1 being greater than or equal to 0.15 mm and less than or equal to at 0.45 mm; eight son of diameter d2 forming an outer layer (C2) of the strand, the eight son being 2969181-4 wound in a pitch P2 around the intermediate layer (Cl) of the strand, the diameter d2 being greater than or equal to 0.15 mm and lower or equal to 0.45 mm; in which the ratio of diameters d0 / d1 is greater than or equal to 0.3 and less than or equal to 0.4. [0015] The invention also relates to the use of such multistrand cables for the reinforcement of articles or semi-finished products of rubber, for example webs, pipes, belts, conveyor belts, tires. The multistrand cable of the invention is particularly intended to be used as a reinforcing element for a tire belt intended for industrial vehicles such as "heavy goods vehicles" - ie, subway, bus, transport equipment. road transport (trucks, tractors, trailers), off-the-road vehicles - agricultural or engineering machinery, other transport or handling vehicles. The invention further relates to these articles or semi-finished rubber products themselves when reinforced by a multitoron cable according to the invention, in particular the tires especially for industrial vehicles. The invention as well as its advantages will be readily understood in the light of the description and the following exemplary embodiments, as well as FIGS. 1 to 4 relating to these examples. BRIEF DESCRIPTION OF THE DRAWINGS [0019] FIG. 1 schematically represents, in section perpendicular to the axis of the strand, a strand of construction 1 + 3 + 8, of the type with cylindrical layers, usable in the outer layer of a multistrand cable. according to the invention. Figure 2 shows schematically, in section perpendicular to the axis of the cable, an example of multitoron cable according to the invention, of cylindrical construction (1 + 6) x (1 + 3 + 8), incorporating the strand FIG. 3 schematically represents an example of a twisting and in situ scrubbing installation that can be used for the manufacture of strands intended for the manufacture of the multistrand cable of the invention. [0022] FIG. 4 schematically represents, in radial section, a tire casing for an industrial vehicle having a radial carcass reinforcement, whether or not in accordance with the invention in this general representation. 2969181 -5 MEASUREMENTS AND TESTS M1 - DYNAMOMETRIC MEASUREMENTS [0023] For metal wires and cables, the breaking force measurements denoted FM (maximum load in N), breaking strength denoted RM (in 5 MPa ) and elongation at break noted AT (total elongation in%) are performed in tension according to the ISO 6892 standard of 1984. M2 - AIR PERMEABILITY TEST [0024] This test makes it possible to determine the longitudinal permeability of the air of the metal cables tested, by measuring the volume of air passing through a specimen under constant pressure for a given time. The principle of such a test, well known to those skilled in the art, is to demonstrate the effectiveness of the treatment of a cable to make it impermeable to air; it has been described for example in ASTM D2692-98. The test is here performed on multitasking raw manufacturing cables, or extracted from tires or rubber sheets that reinforce these cables 15 multitorons, so already coated with rubber in the cooked state. In the first case (raw multitasking cables manufacturing), the metal cables must be previously coated from the outside with a so-called coating gum. For this, a series of 10 metal cables arranged in parallel (inter-strand distance: 20 mm) is placed between two skims (two rectangles of 80 x 200 mm) of a rubber composition in the raw state, each skim having a thickness of 5.0 mm; the whole is then locked in a mold, each of the strands being maintained under a sufficient tension (for example 3 daN) to ensure its straightness during the establishment in the mold, using clamping modules; then the vulcanization (baking) is carried out for about ten to twelve hours at a temperature of about 120 ° C and a pressure of 15 bar (rectangular piston 80 x 200 mm). After which, the assembly is demolded and cut 10 pieces of wire rope and coated, in the form of parallelepipeds of dimensions 10 mm x 10 mm x LT, for characterization. A conventional rubber composition for a tire based on natural rubber (peptized) and carbon black N330 (50 phr), comprising the following customary additives: 2969181 -6 sulfur, is used as a coating rubber. (7 phr), sulfenamide accelerator (1 phr), ZnO (8 phr), stearic acid (0.7 phr), antioxidant (1.5 phr) and cobalt naphthenate (1.5 phr). Its Mooney viscosity at 100 ° C is about 70, its toasting time (T5) at 130 ° C is about 10 minutes. For the measurement of Mooney plasticity, an oscillating consistometer is used as described in the French standard T43-005 (1991), according to the following principle: the composition in the raw state (ie, before firing) is molded in a cylindrical chamber heated to 100 ° C. After one minute of preheating, the rotor rotates within the specimen at 2 revolutions / minute and the useful torque is measured to maintain this movement after 4 minutes of rotation. The Mooney plasticity (ML 1 + 4) is expressed in "Mooney unit" (UM, with 1 UM = 0.83 Nm). The measurement of the roasting time is carried out at 130 ° C, in accordance with the NF-T43-005 standard. The evolution of the consistency index as a function of time makes it possible to determine the toasting time of a rubber composition, evaluated in accordance with the above-mentioned standard by the parameter T5, expressed in minutes, and defined as the time required for obtain an increase in the value of the consistometric index (expressed in "Mooney unit") of 5 units above the minimum value measured for that index. The test is carried out on a predetermined length of LT wire rope (for example equal to P3, or 6 cm), thus coated by its surrounding rubber composition (or coating gum), in the following manner: air is sent to the inlet of the strand at a pressure of 1 bar, and the volume of air at the outlet is measured using a flow meter (calibrated for example from 0 to 500 cm3 / min). During the measurement, the strand sample is locked in a compressed seal (for example a dense foam or rubber seal) in such a way that only the amount of air passing through the wire rope from one end to the other other, along its longitudinal axis, is taken into account by the measure; the tightness of the seal is checked beforehand with the aid of a solid rubber specimen, that is to say without cable. The average air flow rate (average on the 10 test pieces) is all the lower as the longitudinal imperviousness of the wire rope is high. As the measurement is made with an accuracy of ± 0.2 cm3 / min, measured values less than or equal to 0.2 cm3 / min are considered to be zero; they correspond to a strand that can be described as airtight (totally airtight) along its axis (i.e., in its longitudinal direction). In the air permeability test, an "airtight" metal cable is characterized by an average air flow rate of less than or equal to 0.2 cm 3 / min while a wire rope called "almost airtight" is characterized by an average air flow rate of less than 2 cm3 / min, preferably less than 1 cm3 / min.

DETAILED DESCRIPTION OF THE INVENTION [0033] In the present description, unless expressly indicated otherwise, all the percentages (%) indicated are% by weight. On the other hand, any range of values designated by the expression "between a and b" represents the range of values from more than a to less than b (that is, terminals 10a and b). excluded) while any range of values designated by the term "from a to b" means the range from a to b (i.e., including strict bounds a and b). By "metallic" cable, the term "definition" in the present application is understood to mean a cable formed of wires constituted mainly (that is to say for more than 50% by number of these threads) or integrally (for 100% wires) of a metallic material. The wires are preferably made of steel, more preferably of carbon steel. But it is of course possible to use other steels, for example a stainless steel, or other alloys. When carbon steel is used, its carbon content (% by weight of steel) is preferably between 0.4% and 1.2%, especially between 0.5% and 1.1%. % these levels represent a good compromise between the mechanical properties required for the tire and the feasibility of the wires. It should be noted that a carbon content of between 0.5% and 0.6% makes such steels ultimately less expensive because easier to draw. Another advantageous embodiment of the invention may also consist, depending on the applications concerned, of using steels with a low carbon content, for example between 0.2% and 0.5%, especially because of lower cost and easier wire drawing. The metal or steel used, whether it is in particular a carbon steel or a stainless steel, may itself be coated with a metal layer 30 improving for example the properties of implementation of the wire rope and / or its constituent elements, or the properties of use of the cable and / or of the tire themselves, such as adhesion properties, corrosion resistance or even corrosion resistance. aging resistance. According to a preferred embodiment, the steel used is covered with a layer of brass (Zn-Cu alloy) or zinc; it is recalled that during the wire manufacturing process, the coating of brass or zinc facilitates the drawing of the wire, as well as the bonding of the wire with the rubber. However, the wires could be covered with a thin metallic layer other than brass or zinc, for example having the function of improving the corrosion resistance of these wires and / or their adhesion to the rubber, for example a thin layer. Co, Ni, Al, an alloy of two or more of Cu, Zn, Al, Ni, Co, Sn. The strands used in the multistrand cable of the invention are preferably made of carbon steel and have a tensile strength (RM) preferably greater than 2500 MPa, more preferably greater than 2800 MPa. The total elongation at break (denoted At) of each constituent strand of the cable of the invention, the sum of its structural, elastic and plastic elongations, is preferably greater than 2.0%, more preferably at least 2, 5%.

MULTITORON CABLE ACCORDING TO THE INVENTION I - STRUCTURE [0039] The multistrand metal cable of the invention consists of a core (that is to say, as a reminder, of a support of the outer layer) comprising a single strand forming an inner layer (Cl) of the cable. Around this core are spirally wound, at a helical pitch P3 preferentially between 20 and 80 mm, six outer strands which form an outer layer (CE) of the cable around the inner layer (Cl) of the cable. It will be recalled here that in a known manner the pitch "P" represents the length, measured parallel to the axis of the outer strand or of the multistrand cable, at the end of which a wire or an outer strand, respectively, having this pitch performs a complete revolution about said axis. Each strand consists of a cable with two layers of construction "1 + 3 + 8", comprising a single wire of diameter d0 forming an inner layer (CO) of the strand, three son of diameter d1 forming an intermediate layer (Cl) of the strand, helically wound in a pitch P1 around the inner layer (CO) of the strand and an outer layer (C2) of the strand consisting of eight d2 diameter wires helically wound in a pitch P2 around the intermediate layer (Cl) of the strand. For each of these strands, the diameter d1 and the diameter d2 are preferably greater than or equal to 0.15 mm and less than or equal to 0.45 mm and the pitch P2 is preferably greater than or equal to 10 mm and less than or equal to equal to 30 mm. The ratio of diameters d0 and dl is greater than or equal to 0.3 and less than or equal to 0.4. The following relationship is preferably verified: 1.5 5 P3 / P2 5 6.0. More preferably, the following relationship is verified: 2.0 P3 / P2 5.5 and even more preferably the relation 2.5 5 P3 / P2 4.5, or even 2.5 5 P3 / P2 3.0. The choice of the ratio d0 / d1 and providing an outer layer (C2) of the strand having eight son have the consequence that the average distance between the son of the intermediate layer (Cl) and outer (C2) of the strand is sufficient to facilitate the penetration of the gum to the heart of the strands. For an optimized compromise between strength, feasibility, rigidity and compressive endurance of the cable, it is preferred that the diameter dl son forming an intermediate layer (Cl) of the strand is greater than or equal to 0.20 mm and less than or equal to 0.40 mm, and preferably greater than or equal to 0.22 mm and less than or equal to 0.38 mm, and that the diameter d2 of the son forming the outer layer (C2) of the strand, identical or not to the son forming the intermediate layer (Cl) of the strand , greater than or equal to 0.20 mm and less than or equal to 0.40 mm, and preferably greater than or equal to 0.22 mm and less than or equal to 0.38 mm. The son of the intermediate layer (Cl) of the strand and the outer layer (C2) of the strand may have the same diameter or different from one layer to another. Wire of the same diameter can be used from one layer to another (ie dl = d2), which simplifies the manufacture of the strands and reduces their cost. Preferably, in each strand, the pitch P2 is greater than or equal to 10 mm and less than or equal to 30 mm, and even more preferably greater than or equal to 12 mm and less than or equal to 18 mm. According to a preferred embodiment, the pitch P1 is greater than or equal to 5 mm and less than or equal to 15 mm. A pitch greater than 15 mm has the effect of making the outer layer (CE) of the cable less round. Preferably, P1 satisfies the relationship: 20 <P1 / d1 <100, and more preferably the relation: 25 <P1 / d1 <75. According to another preferred embodiment, the following relationship is preferably verified: 0.5 5 P1 / P2 5 1. [0051] Preferably, the strands of the outer layer (CE) of the cable are cylindrical . Such a configuration can be achieved in particular by two distinct paths. According to a first variant, the wires forming the intermediate layer (C1) and the outer layer (C2) of the strands of the outer layer (CE) of the cable are wound at a different pitch (P10 P2). This configuration results in a well circular and more regular assembly. The penetration of the rubber in the strand is facilitated. The winding in the same direction of the C1 and C2 layers advantageously allows to minimize the friction between these two layers and therefore the wear of the son constituting them. According to a second variant, the wires forming the intermediate layer (C1) and the outer layer (C2) of the strands of the outer layer (CE) of the cable are wound in a different direction of twist (S / Z or Z / S), possibly with the same pitch (P1 = P2). Thus the space between the strands, outside the points of contact between strands, is enlarged. In configurations where the pitch P1 is different from the pitch P2, it is preferable that the pitch P1 is less than the pitch P2, and even more preferably, the pitch P1 is equal to half the pitch P2. This configuration makes it possible to better distribute the wires 20 around the intermediate layer (C1) of the strand. The winding direction of the strands of the outer layer (CE) of the cable around the inner layer (Cl) of the cable is preferably opposite with respect to the winding direction of the wires of the intermediate layer (Cl) and of the outer layer of the outer layer of the cable. The pitch P3 of the strands of the outer layer (CE) of the cable is preferably greater than or equal to 20 mm and less than or equal to 80 mm, and still more preferably greater than or equal to 30 mm and less than or equal to 70 mm, in particular between 30 and 60 mm. The diameters d1 and d2 may be identical (which simplifies the manufacture of the cable) or different. If the diameters are different, it is preferable that the diameter d1 is greater than the diameter d2. The yarns of the two layers (C1, C2) may have the same diameter (either d1 = d2) or different diameters (or d1 0 d2) from one layer (Cl) to the other ( C2), provided that the eight wires of said outer layer (C2) of the strand do not contact each other [0058] Preferably, the strands forming the inner layer (C1) of the cable and the strands forming the outer layer (CE) of the cable are identical, which simplifies the manufacture of the cable. FIG. 1 schematically represents, in section perpendicular to the axis of the strand, a strand 10 of construction 1 + 3 + 8, of the type with cylindrical layers, usable in a multistrand cable according to the invention. A son 11 forms the inner layer (CO) of the strand and three son 12 of diameter d1 form the intermediate layer (Cl) of the strand. The outer layer (C2) of the strand consists of eight son 13 of diameter d2 helically wound in a pitch P2 around the intermediate layer (Cl) of the strand. The diameters d1 and d2 are here identical (in this case 0.35 mm); the ratio d0 / d1 is equal to 0.12 / 0.35 = 0.34. The number of wires of the outer layer (C2) of the strand is less than the maximum number of wires of diameter d2 which can be helically wound in a single layer around the intermediate layer (Cl) of the strand. The son forming the outer layer (C2) of the strand do not touch. FIG. 2 diagrammatically shows, in section perpendicular to the axis of the cable (assumed to be rectilinear and also at rest), an example of a multistrand cable 100 according to the invention, of construction (1 + 6) x (1 + 3 + 8) or, according to an equivalent nomenclature 1x (1 + 3 + 8) + 6x (1 + 3 + 8). In this example, each of the seven strands 10, that is to say the central strand constituting the inner layer (Cl) of the cable as the six strands forming the outer layer (CE) of the cable that surround it, have the same Construction (1 + 3 + 8) corresponding to the elementary strand 10 previously described in FIG. 1. This multistrand 100 cable is composed of elementary strands 10 having an outer layer (C2) easily penetrable by rubber, which gives it a improved endurance against corrosion fatigue. The cable 100 may be provided with an outer hoop 110 constituted by a unitary fine wire helically wound around the six outer strands, in a direction (S or Z) identical to or opposite to that of said outer strands, but the presence of such a band is not an essential characteristic of a cable according to the invention. The multistrand cables of the invention, such as the previously described strand which constitutes them, can be of two types, namely preferably of the compact type 2969181 -12- or of the type with cylindrical layers. They may or may not be provided with an outer hoop 110 constituted by a unitary fine wire helically wound around the six outer strands, in a direction (S or Z) identical to or opposite to that of said outer strands.

II - FABRICATION MANUFACTURING OF ELEMENTARY TORONS [0062] The elementary strands of construction 1 + 3 + 8 previously described are manufactured according to known methods comprising the following steps, preferably carried out online and continuously: firstly, a step assembling by twisting or cabling the three core wires around a single wire forming the inner layer (CO), for forming the intermediate layer (C1) of the strand at an assembly point; optionally, downstream of said assembly point of the three core wires, a step of sheathing the inner (CO) and intermediate (Cl) layers of the strand by the filling gum in the green state (that is, say non-crosslinked); followed by a step of assembling by twisting or wiring the eight son of the outer layer (C2) of the strand around the intermediate layer (Cl) of the strand; preferably a final balancing step of the twists, in particular during sheathing. It will be recalled here that there are two possible techniques for assembling metal wires: either by wiring: in such a case, the wires do not undergo torsion around their own axis, because of a synchronous rotation before and after the point of assembly; 25 or by twisting: in such a case, the yarns undergo both a collective twist and an individual twist around their own axis, which generates a detorsion torque on each son. A preferred feature of the above method is to use, both for the assembly of the intermediate layer (C1) of the strand and for that of the outer layer (C2) of the strand, a twisting step. During the first step, the three core wires are twisted together (direction S or Z) around a single wire forming the inner layer (CO), for formation of the intermediate layer ( Cl) of the strand, in a manner known per se; the yarns are delivered by feeding means such as bobbins, a distribution grid, coupled or not to an assembly line, intended to converge the core wires into a common point of torsion (or point d 'assembly). The intermediate layer (Cl) of the strand thus formed can then be sheathed in green filling gum, provided by an extrusion screw at a suitable temperature. The filling rubber can thus be delivered at a fixed, single point 10 and of small dimensions, by means of a single extrusion head, without resorting to individual sheathing of the yarns upstream of the assembly operations, before forming of the intermediate layer, as described in the prior art. This method has the significant advantage of not slowing down the conventional assembly process. It makes possible the complete operation of initial twisting, scrubbing and final twisting in line and in a single step, regardless of the type of strand produced (compact strand as strand with cylindrical layers), all this at high speed. Finally, we proceed to the final assembly, preferably by twisting (S or Z direction) of the eight son of the outer layer (C2) of the strand around the intermediate layer (Cl) of the strand and sheathed. The optional step that follows consists in passing the strand through torsion balancing means. "Torsional balancing" here means, in a manner well known to those skilled in the art, the cancellation of the residual torsion torques (or of the springback of untwisting) exerted on each strand wire, in the intermediate layer ( C1) of the strand as in the outer layer (C2) of the strand. After this final step of balancing the torsion, the manufacture of the outer strand is completed. This strand is wound on one or more reception coils, for storage, before the subsequent operation of wiring the elementary strands to obtain the multistrand cable of the invention. This manufacturing method naturally applies to the manufacture of external strands of the compact type (for recall and by definition, those for which the intermediate layer (Cl) of the strand and the outer layer (C2) of the strand are wound at the same pitch and in the same direction) as cables of the type with cylindrical layers (for recall and by definition, those for which the intermediate layer (Cl) of the strand 2969181 -14- and the outer layer (C2) of the strand are wrapped either in different steps or in opposite directions, or in different steps and in opposite directions). An assembly and scrubbing device that can be used for the implementation of the process described above is a device comprising from upstream to downstream, according to the direction of advancement of a strand being formed: core supply; feed means for feeding the three core threads; assembly means by twisting or cabling the three core wires, for forming the intermediate layer (Cl) of the strand around a single wire forming the inner layer (CO); optionally, cladding means of the intermediate layer (Cl) of the strand; assembly means by twisting or cabling the eight outer son around the intermediate layer (Cl) of the strand and sheathed, for forming the outer layer (C2) of the strand; And optional means for balancing torsion. FIG. 3 shows an example of a twisting device, of the type with rotating feed and receiving, which can be used for the manufacture of a strand of the type with cylindrical layers (not p1 and p2 different and / or sense of different torsion of the layers C1 and C2), for example of construction 1 + 3 + 8 as illustrated in FIG.

In this device 200, supply means 210 deliver core threads 11 and 12 through a distribution grid 211 (axisymmetrical distributor), coupled or not to an assembly grain 212, beyond which converge the son 12 at an assembly point or twisting point 213, for forming the intermediate layer (Cl) of the strand around a single wire 11 forming the inner layer (CO) ,. The inner layer C1, once formed, can then pass therethrough an optional cladding zone consisting for example of a single extrusion head 214 through which the inner layer is intended to flow. The distance between the point of convergence 213 and the sheathing point 214 is for example between 50 cm and 1 m. Around the intermediate layer (Cl) of the strand, optionally gummed, progressing in the direction of the arrow, are then assembled by twisting the wires 13 of the outer layer (C2) of the strand delivered by supply means 220. Strand C0 + C1 + C2 thus formed is finally collected on a rotary reception 240, after passing through the torsion balancing means 230 consisting for example of a trainer or a twister-trainer. It will be recalled here that, in a manner well known to those skilled in the art, for the manufacture of a 1 + 3 + 8 strand of the compact type (not identical p1 and p2 and identical direction of torsion of the Cl layers and C2), a device 200 will be used, this time comprising only one rotating (feeding or receiving) element, and not two as shown schematically in FIG. 3 by way of example. MANUFACTURE OF MULTITORON CABLE [0076] For the manufacture of the multistrand cable of the invention, it is well known to those skilled in the art, by wiring or twisting the elementary strands previously obtained, using cabling machines. or twisting dimensioned to assemble strands. III - USE OF THE CABLE [0077] The multistrand cable of the invention may be used for reinforcing articles other than tires, for example pipes, belts, conveyor belts; advantageously, it could also be used for reinforcing parts of tires other than their crown reinforcement, in particular for reinforcing the carcass reinforcement of tires for industrial vehicles. However, as explained in the introduction to this memo, the cable of the invention is particularly intended for a tire crown reinforcement for large industrial vehicles such as civil engineering, in particular of the mining type. By way of example, FIG. 4 very schematically represents a radial section of a metal crown reinforcement tire which may or may not be in conformity with the invention, in this general representation. This tire 1 has a top 2 reinforced by a crown reinforcement or belt 6, two sides 3 and two beads 4, each of these beads 4 being reinforced with a rod 5. The top 2 is surmounted by a strip of rolling. A carcass reinforcement 7 is wound around the two rods 5 in each bead 4, the upturn 8 of this armature 7 being for example disposed towards the outside of the tire 1 which is shown here mounted on its rim 9. The armature of carcass 7 is in known manner constituted of at least one ply reinforced by so-called "radial" cables, that is to say that these cables are arranged substantially parallel to each other and extend from one bead to the other so as to form an angle of between 80 ° and 90 ° to the median circumferential plane (i.e. the plane which is perpendicular to the axis of rotation of the tire and which is located halfway between the two beads 4, this plane passes through the axial center of the crown reinforcement 6). The tire according to the invention is characterized in that its belt 6 comprises at least, as reinforcement of at least one of the belt plies, a multitoron cable according to the invention. In this belt 6 diagrammatically shown in FIG. 4, it will be understood that the multistrand cables of the invention may, for example, reinforce all or part of the so-called "working" belt plies. Of course, this tire 1 also comprises, in a known manner, an inner rubber or elastomer layer (commonly called "inner rubber") which defines the radially inner face of the tire and which is intended to protect the carcass ply from the diffusion of the tire. air from the interior space to the tire. IV - EXAMPLES OF EMBODIMENTS The following tests demonstrate the ability of the invention to provide multi-toned cables whose endurance, in particular in the tire belt, can be significantly increased thanks to an excellent property of core penetration. Cables. NATURE AND PROPERTIES OF THE WIRES AND CABLES USED As elementary strands, the following tests use strands with two or three layers of constructions 3 + 8 or 1 + 3 + 8 as shown diagrammatically in FIG. , consisting of fine wire made of carbon steel coated with brass. The carbon steel son are prepared in a known manner, for example starting from machine wires (diameter 5 to 6 mm) that are first cold-rolled, by rolling and / or drawing, to a maximum intermediate diameter of about 1 mm. The steel used for the cable according to the invention is, for example, a high strength carbon steel having a carbon content of about 0.9%, having about 0.2% chromium, the the remainder being made of iron and the usual unavoidable impurities related to the steelmaking process. [0085] The intermediate diameter son undergo a degreasing treatment and / or pickling, before their subsequent processing. After deposition of a brass coating on these intermediate son, is carried on each wire a so-called "final" work hardening (ie, after the last patenting heat treatment), by cold drawing in a wet medium with a drawing lubricant which is for example in the form of an aqueous emulsion or dispersion. The steel wires thus drawn have the following diameter and mechanical properties: Steel cP (mm) FM (N) RM (MPa) NT 0.23 113.5 2830 HT 0.35 275 2900 SHT 0.35 290 3040 Table 1 [0087] These wires are then assembled in the form of strands whose mechanical properties are given in Table 2: Wire Grade P1 P2 P3 FM Wire RM (mm) (mm) (mm) (daN) (MPa) (3 + 9) x 0.35 HT 7.7 15.4 - 295 2530 (3 + 8) x 0.35 HT 7.7 15.4 - 270 2530 1x0.12 + (3 + 8) x0.35 SHT INF 7.7 15.4 298 2750 Table 2 [0088] For the manufacture of these strands, it was used assembly means by twisting. Table 3 presents the different cables obtained from these strands: Letter Structure "A" (3 + 9) x 0.35 + 6 x (3 + 9) x 0.35 + fret "B" (3 +8) x 0.35 + 6 x (3 + 8) x 0.35 + fret "C" (0.12 + 3 + 8) x 0.35 + 6 x (0.12 + 3 + 8) x 0.35 + fret Table 3 [0090] The letter "A" corresponds to a cable (1 + 6) x (3 + 9) as known, for example, from JP 08 109 585. The letter "B" corresponds to a reference cable 5 (1 + 6) x (3 + 8) as known, for example, from JP 2009-52177. The comparison of the letters "A" and "B" makes it possible to highlight the effect of the "desaturation" of the outer layer of the strands of the outer layer of the cable, the comparison of the letters "B" and "C". effect of the central nucleus. Table 4 presents certain geometrical and dynamometric characteristics of these cables: Letter Unit "A" "B" "C" Diameter NF mm 4.34 4.34 4.55 FM daN 2042 1873 2050 RM MPa 2480 2480 2670 Table 4 RESULTS OF TESTS [ 0092] Table 5 presents the results of air permeability tests. This permeability is characterized both by an average air flow (average over 10 measurements) and by NPO, that is to say the number of measurements corresponding to a zero air flow rate. 2969181 -19- Letter Unit "A" "B" "C" Average flow cm3 / min> 400 50 5 NPO% 0 0 50 Table 5 [0093] The comparison between the letters "A" and "B" shows that the desaturation of the strands of the outer layer of the strands of the outer layer of the cable has the effect of considerably reducing the air flow. In other words, the desaturation of the strands allows effective penetration of the rubber into the saturated construction cable, while the "1 + 6" construction cables are considered impenetrable. The effect is further amplified for the letter "C". Note also the very significant increase in the number of measurements corresponding to a zero air flow. This better penetration is also clearly visible in the observation of 10 cross sections under a microscope. In conclusion, thanks to the specific construction of the strands of the outer layer and the high permeability to the rubber compounds that characterizes them, the multistrand cable according to the invention is capable of having improved fatigue-corrosion endurance. 15

Claims (13)

REVENDICATIONS1. Two-layer multi-strand metal cable (Cl, CE) of strand, of "1 + 6" construction, usable in particular for the reinforcement of tires for industrial vehicles, comprising a single strand forming an inner layer (Cl) of the cable, in which six strands are wound, helically, in a pitch P3, to form an outer layer (CE) of the cable around the inner layer (Cl) of the cable, each strand consisting of a cable with three layers of construction "1 + 3 +8 ", comprising: a wire of diameter d0 forming an inner layer (CO) of the strand; three wires of diameter d1 forming an intermediate layer (Cl) of the strand, the three wires being wound in a pitch P1 around the inner layer (CO) of the strand, the diameter d1 being greater than or equal to 0.15 mm and less than or equal to 0.45 mm; eight son of diameter d2 forming an outer layer (C2) of the strand, the eight son being wound in a pitch P2 around the intermediate layer (Cl) of the strand, the diameter d2 being greater than or equal to 0.15 mm and less than or equal to 0.45 mm; in which the ratio of diameters d0 / d1 is greater than or equal to 0.3 and less than or equal to 0.4. Multistrand metal cable according to claim 1, wherein the diameter d1 is greater than or equal to 0.20 mm and less than or equal to 0.40 mm, and preferably greater than or equal to 0.22 mm and less than or equal to 0.38 mm, and wherein the diameter d2 is greater than or equal to 0.20 mm and less than or equal to 0.40 mm, and preferably greater than or equal to 0.22 mm and less than or equal to 0.38 mm A multistrand metal cable according to any of claims 1 or 2, wherein in each strand the pitch P2 is greater than or equal to 10 mm and less than or equal to 30 mm. 2969181 -21 - Multitone metal cable according to any one of claims 1 to 3, wherein the pitch P1 is greater than or equal to 5 mm and less than or equal to 15 mm. A multistrand metal cable according to any one of claims 1 to 4, wherein the wires forming the intermediate layer (C1) and the outer layer (C2) of the strands of the outer layer (CE) of the cable are wound in a different twist direction (S / Z or Z / S). 6. A multistrand metal cable according to claim 5, wherein the son forming the intermediate layer (C1) and the outer layer (C2) of the strands of the outer layer (CE) of the cable are wound at the same pitch (P1 = P2). 10 Multistrand metal cable according to any one of claims 1 to 4, wherein the wires forming the intermediate layer (C1) and the outer layer (C2) of the strands of the outer layer (CE) of the cable are wound at a step different (P1 # P2). The multistrand metal cable according to claim 7, wherein the direction of twisting of the intermediate layer (C1) wires and the direction of twisting of the outer layer (C2) strands of the outer layer (CE) strands. cable are identical. Multistrand metal cable according to any one of claims 1 to 8, wherein the direction of twist of the strands of the outer layer (CE) of the cable around the inner layer (Cl) of the cable is opposite to the direction of twisting the wires of the intermediate layer (C1) and the outer layer (C2) of the strands of the outer layer (CE) of the cable. 10. A multistrand metal cable according to any one of claims 1 to 5 or 7 to 9, wherein the pitch P1 is less than the pitch P2. The multistrand metal cable according to claim 10, wherein the pitch P1 is equal to half the pitch P2. The multistrand metal cable according to any of claims 1 to 11, wherein the pitch P3 of the strands of the outer layer (CE) of the cable is greater than or equal to 20 mm and less than or equal to 80 mm. , and preferably greater than or equal to 30 mm and less than or equal to 70 mm. 13. Multitone metal cable according to any one of claims 1 to 12, wherein the diameters dl and d2 are identical. 5