Process and equipment for producing a rubber for a tire comprising a kneading step

Abstract

In the process for producing a rubber for manufacturing a tire: a calender forms a ply with a mixture of ingredients of the rubber while a conveyor moves the ply in a first direction, a mass of product other than the rubber is deposited on the ply, and the conveyor displaces the ply in a second direction, such that the mass is arranged between two faces of the ply extending one against the other.

Claims

1. Process for producing a rubber for manufacturing a tire, comprising: forming a ply by a calender with a mixture of ingredients of the rubber whilst a conveyor moves the ply in a first direction, depositing a mass of product other than the rubber on the ply, and moving the ply by the conveyor in a second direction, such that the mass is arranged between two faces of the ply extending one against the other.

2. Process according to claim 1, wherein the ply is circulated in the form of a closed loop.

3. Process according to claim 2, wherein a device comprising the calender and the conveyor opens the loop so as to form two free ends of the ply.

4. Process according to claim 1, wherein the product forming the mass comprises a compound promoting the vulcanization of the rubber.

5. Process according to claim 1, wherein the product is deposited only once a temperature of the ply has become lower than a predetermined threshold.

6. Process according to claim 1, wherein the ply is discharged from a device comprising the calender and the conveyor, together with the mass arranged between the two faces extending one against the other.

7. Process according to claim 6, wherein the conveyor carries out the discharge in the second direction.

8. Equipment for producing a rubber, able to carry out a process according to claim 1, and which comprises a calender, a first conveyor, and a second conveyor, the equipment being able to circulate the ply in a closed loop by passing the ply through the calender and on the first conveyor which moves the ply in the first direction, the second conveyor being able to dispense the mass directly onto a portion of the ply carried by the first conveyor when the ply circulates in a closed loop, the first conveyor being then able to move the ply in a second direction, such that the mass is arranged between two faces of the ply extending one against the other.

9. Equipment according to claim 8, further comprising cooling means within the calender.

10. Equipment according to claim 8, wherein an end of the second conveyor is located upstream of the calender with respect to a discharge direction, the discharge direction being defined as movement of the first conveyor in a direction outside of the equipment.

11. Equipment according to claim 8, further comprising a third conveyor, which is inclined with respect to the vertical direction and has an end arranged above the calender.

12. Equipment according to claim 11, further comprising cooling means within the third conveyor.

13. Equipment according to claim 11, wherein the second conveyor has an end arranged below the third conveyor.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features and advantages of the invention will become clearer from the following description of a non-limiting embodiment given by way of example and with reference to the accompanying drawings, in which:

(2) FIGS. 1 and 2 show a plan view and a view from above respectively of a kneading station of a piece of equipment for producing a rubber according to an embodiment of the invention; and

(3) FIGS. 3, 4 and 5 illustrate successive steps of the present embodiment of the process of the invention by means of the equipment in FIGS. 1 and 2.

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS

(4) A station 2 of a piece of equipment for producing a rubber for a tire according to an embodiment of the invention has been illustrated in FIGS. 1 and 2. The tire may be a tire for the wheels of a lightweight vehicle, a passenger vehicle, a utility vehicle, a heavy goods vehicle, or else for the wheels of an engineering machine.

(5) The station 2 comprises a lower horizontal belt 4 in the form of an endless band able to circulate whilst being held and driven between two rolls 6, of which the axes defining the axes of rotation are horizontal and mounted rotatably relative to a frame 8 of the station. The two walls of the belt are horizontal.

(6) Similarly, the station comprises a vertical belt 8 provided in the form of an endless band able to circulate whilst being held and driven between one of the rolls 6 and a roll 10 extending above the first-mentioned roll. The two walls of the belt 8 are vertical.

(7) The station 2 also comprises a rising belt 12 in the form of an endless loop able to circulate whilst being supported and driven by an upper roll 14 and a lower roll 16 of greater diameter than the roll 14. The roll 14 extends at a distance from the roll 16 in the horizontal direction and in the vertical direction. The belt 12 comprises inner cooling means 33 arranged between the two layers of the band or in at least one of the rolls 6, 10.

(8) The station 2 further comprises a calender 18 comprising two identical cylinders 20 arranged in a mutually opposed manner with their geometric axes of rotation 22 parallel to one another. The two rolls extend at a distance from one another and above the horizontal belt. The calender comprises cooling means 34 within the rolls.

(9) All the axes of the aforementioned rolls 6, 10, 14, 16 as well as the axes 22 of the cylinders are horizontal and parallel to one another.

(10) The station 2 also comprises a horizontal introduction belt 24 having a band in the form of a closed loop able to circulate whilst being held and driven by two rolls 26 having horizontal axes 28 parallel to one another and perpendicular to the aforementioned axes. The upper horizontal wall of the belt 24 moves in a direction 25 perpendicular to the direction 29 of movement of the wall of the lower belt 4. In addition, the belt 24 is able to circulate such that the products arranged on its upper face are discharged therefrom via the end 27 located in the upper part of FIG. 1. This end extends above the lower belt 4, opposite the latter, approximately halfway between its ends formed by the rolls 6.

(11) Lastly, the station comprises a transfer belt 30 having a band provided in the form of a closed loop able to circulate whilst being held and driven by rolls 32, of which only one is visible in FIG. 2. This roll has an axis parallel to that of the roll 6 and extends below the latter.

(12) The roll 14 extends above one of the cylinders 20, without covering the other cylinder 20. The rising belt 12 extends above part of the introduction belt 24 and in particular from its discharge end. The roll 16 extends opposite the two belts 4 and 8 and the cylinder 6 supporting said two belts. The introduction belt 24 is located to the side of the calender 18, without being arranged in the vertical extent thereof.

(13) The equipment is controlled so as to carry out the process of the invention in the following manner.

(14) In a station (not illustrated) of the equipment, a natural elastomer, a synthetic elastomer, and a charge formed for example by carbon black or silica are mixed in a tank, said station being arranged upstream of the station 2. At this stage, vulcanizing product is not incorporated in the mixture.

(15) At the end of this mixing phase, the mixture is discharged via a lower opening in the tank and this rubber mass 35 is transferred towards the station 2 of the equipment.

(16) The rubber mass 35 passes in the calender 18 between the cylinders 20 turning in opposite directions and forms a ply. The lower belt 4 is moved such that its upper wall moves towards the left as indicated in FIG. 3. The vertical belt 8 is moved such that its right-hand wall moves upwards. The rolls 14 and 16 are turned in a clockwise direction such that the upper wall of the belt 12 rises during the movement of this belt.

(17) During its passage through the calender, the rubber forms a ply which deposits on the upper wall of the lower belt 4 and is transferred in the direction of the vertical belt.

(18) An operator places an end part of this ply around the lower roll 16, such that this part is driven over the rising belt, passing between this belt and the vertical belt 8. The ply travels over the rising belt 12, passes the roll 14, and falls again in the direction of the calender, where it accumulates again.

(19) A closed-loop ply is thus formed, which circulates continuously in the clockwise direction, as indicated in FIG. 3, from the calender to the lower belt, then over the rising belt and again through the calender, and does so a number of times. During this movement, the rubber accumulates in the calender upstream of the rolls so as to reform a ply at the exit of said rolls. This circulation thus causes continued mixing and kneading of the ingredients. During this movement, the cooling means 34 lower the temperature of the rubber, which additionally experiences a lowering of its temperature due to its contact with the air and the other elements of the station 2. Whereas its temperature reached 170 C. before its arrival at the station, it reaches approximately 80 C. at the end of this circulation. These values are given merely by way of example. The circulation of the ply for example takes within one and four minutes, preferably over two minutes.

(20) To end this circulation, a reversal of the direction of movement of the rising belt 12 is commanded, as illustrated in FIG. 4, whilst continuing the rotation of the cylinders 20 as before. This leads to a rupture of the ply between the roll 14 and the calender and therefore to the opening of the loop. At the same moment, the reversal of the direction of movement of the lower belt is commanded so as to initiate the movement of the ply in the direction of the transfer belt 30 in the direction 31, that is to say to the right in the figures.

(21) At the same moment also, a block of vulcanizing product 36 is introduced into the station. This product is a mixture of sulphur and a retarder product, for example. This block, in this case, has a rectangular parallelepipedic shape. It forms a product mass proportioned to the constituents of the mixture forming the rubber. The block 36 is introduced via the belt 24, which guides the block via its upper wall as far as the discharge end 27 and dispenses it directly onto a portion 37 of the ply carried by the lower belt 4 and thus being located in the lower half of the latter. The block is therefore arranged on an upper face 38 of a portion 37 of the ply of which the kneading at the station 2 is now complete since this portion will no longer pass again through the calender. At the moment of deposition of the block on the ply, part of the ply is still carried over the entire upper face of the rising belt 12, and another part is carried by the calender 20, through which it is passing for the last time.

(22) During the continuation of the movements of the different elements of the station 2, the portion 37 of the ply carrying the block is moved therewith towards the right, whereas the end portion 39 of the ply passing through the calender is moved progressively over this portion so as to cover it and also the block. The block is therefore arranged between the inner faces of the two portions 37, 39 of the ply extending one against the other and one above the other. A two-layer fold or arrangement is thus formed, in which the block is housed. It should be noted here that the end of the belt 24 is located upstream of the calender with respect to the movement of the belt 4 towards the right.

(23) The continuation of the movement of the rising belt discharges the other end part of the ply towards the horizontal belt. The ply is transferred progressively over the transfer belt 30.

(24) Still in the same configuration with the block between the two ply portions, the assembly is then sent towards a finishing station, where the ply and the vulcanizing block are mixed.

(25) The rubber 35 and the vulcanizing block 36 are thus transported from the station 2 towards the station following the equipment in a configuration such that the block is enveloped in the ply. As a result, material losses of vulcanizing product are avoided during the transfer of this assembly.

(26) It should be stressed that the block 36 is not mixed with the rubber of the ply 35 and is not kneaded therewith within the station 2. These procedures are only performed in a subsequent station of the equipment. It is also stressed that the block is arranged against a face of a part of the ply of which the kneading was completed in the station 2.

(27) The equipment may comprise control means 42 able to control all or some of the process steps just described. These means advantageously comprise one or more computers having microprocessors and memories as well as a program comprising code instructions able to control the execution of these steps when these instructions are run on a computer.

(28) Of course, numerous modifications can be applied to the invention, without departing from the scope thereof.