ITRM20130678A1 - MOLD WITH TWO HALF 'PROVIDED WITH SECTORS, FOR THE PRODUCTION OF TIRES BY VULCANIZATION. - Google Patents

Description

Two-half mold with sectors, for the production of rubber by vulcanization

The present invention relates to a two-half mold provided with sectors, for the production of rubbers by vulcanization.

The invention refers to the field of rubber production and in particular of solid rubber, by vulcanizing a suitable mixture inside a mold.

It is known that the technical characteristics of a rubber (whether it is a tire or a solid tire, also called solid tire) and consequently its ability to satisfy the market performance for which it was designed are mainly guaranteed by four main control fields:

- type of internal structure;

- definition and mixing of the type of materials;

- vulcanization cycle (thermodynamic and temporal parameters); And

- shape of the product.

A product is therefore defined by the correct choice, design and combination of each of these four parameters.

The vulcanization process, although at the process level it takes place between the last stages of product construction, reflects a very important role, as it allows to give shape (through appropriate molds) and consistency (through appropriate thermo-chemical transformations) to the raw (green tire) turning it into a finished product (cured tire).

The mold therefore assumes fundamental importance, as it molds the product into its final shape, correlating it both to factors of pure performance (geometry of the cavity and design of the tread) and to purely aesthetic / commercial factors (elimination of molding problems, marking / lettering functional and aesthetic). For this reason, the correct definition of the mold reflects a fundamental role in the final appearance of the rubber product.

However, the geometries of the final product (and therefore in the negative, of the mold) must be subject to printability parameters which are in turn linked to the mold technology. In fact, as occurs for metal and plastic materials, the presence of undercuts and sudden variations in geometry can cause problems, even insurmountable, in molding. This occurs despite the vulcanized rubber used for this type of product, which has much better elasticity and deformation characteristics than plastic and mechanical materials, for which this problem is much more felt.

In the field of solid tires (often referred to as solid tires) historically a type of molding based on two-half molds mounted on two-deck presses, with extraction by automatic or manual ejector has always been used. Figure 1 illustrates the molding solution in question, and in particular only one half of a mold is shown in section, but it should be understood that, since the mold is intended for the production of a rubber, it will have an overall circular structure, i.e. will have a second half (not shown), which in this case is to the right of the mold half that is shown. In particular, in figure 1 it is possible to identify the cavity 1 of the mold and, in succession, the lower half-mold 2, the lower bead ring 3, the upper half-mold 4 and the upper bead ring 5. The lower half-mold 2 is coupled in a manner fixed to the lower press platen 6, while the upper half-mold 4 and the upper bead ring 5 are fixedly coupled to the upper press platen 7.

In the opening phase of the mold, illustrated with reference to Figure 2, the upper press plane 7 moves upwards together with the upper half-mold 4 and the upper bead ring 5, bound to it, freeing the upper portion of the rubber 8.

During the opening of the mold, due to the effect of the interference that is established between the undercuts 9 and the respective blocks 9 ', a mechanical stress is generated on the tread of the rubber 8 which can cause tears or tears, up to the extreme case of prevent the opening of the press due to insufficient extraction force.

This phenomenon occurs similarly, as illustrated with reference to Figure 3, during the expulsion of the rubber 8 from the lower sub-mold 2, due to the thrust exerted by means of the lower heel ring 3.

In order to avoid these problems, centripetal systems have been developed with the use of molds in sectors derived from the pneumatic sector dedicated to passenger and / or off-road vehicles (passenger / OTR). These systems, in addition to entailing a price increase due to the greater technical difficulty in making the mold, entail the need to equip the production unit with new radial presses with the consequent investment values that are obviously necessary.

In this context, the solution according to the present invention is inserted, which aims to identify a solution that allows for more aggressive and complicated tread geometries, while preserving the factory technological apparatus and the printability of the product.

These and other results are obtained according to the present invention by proposing a new mold technology, characterized by the intersection of the positive solutions of each of the two molding methodologies, or by implementing a sector technology on two-half molds mounted on two-platen presses. , in order to obtain the advantages of a radial system without the need to resort to high investments due to the acquisition of new presses.

The object of the present invention is therefore to provide a two-half mold provided with sectors, for the production of rubbers by vulcanization, which allows to overcome the limits of the two-half molds according to the known technology and to obtain the technical results previously described.

A further purpose of the invention is that said mold can be made with substantially low costs, both in terms of production costs and in terms of management costs.

Not the least object of the invention is to propose a two-half mold provided with sectors, for the production of rubber by vulcanization, which is simple, safe and reliable.

Therefore, the specific object of the present invention is a mold with two halves comprising a lower plate, a lower bead ring, an upper plate, an upper bead ring and a plurality of sectors which all together define a cavity of the mold, said sectors being coupled to a cylindrical ring, arranged externally to them and integral with said lower plate, said sectors being free to translate, between two limit switches, with respect to a conical wall of said cylindrical ring, with the vertex of the ideal continuation of said conical wall from the side of said lower plate , on said sectors acting elastic means which act on said sectors moving them away from said lower plate.

Preferably, according to the present invention, said elastic means are constituted by at least one spring for each sector, housed in a seat of said sector, with axis parallel to the portion of the conical wall arranged along the same radial direction and more preferably said spring engages in a seat formed on the upper surface of the lower plate.

Furthermore, according to the invention, a sliding guide is defined between each of said sectors and said conical wall of said cylindrical ring.

The effectiveness of the mold of the present invention is evident, which allows to pursue a series of advantages, such as:

- the overcoming of the undercut limits deriving from the two-half molding solution;

- the maintenance of the same fleet of presses without the need for significant new investments;

- ease of handling, due to the fact that the mold is essentially characterized by two shells with internal movements;

- the elimination of unsightly circumferential burrs and greater precision in closing the sectors;

- the possibility of developing more complex products;

- greater ease of maintenance of the mold, whose complexity is comparable to that of a sector mold; And

- significant cost savings in the event of a tread change for improvements / replacement / maintenance after failure.

The present invention will now be described, for illustrative but not limitative purposes, according to a preferred embodiment thereof, with particular reference to the figures of the attached drawings, in which:

- figure 1 shows a sectional view of a part of a two-half mold according to the known art, in the closing phase,

- figure 2 shows a sectional view of the mold of figure 1, in the opening phase,

- figure 3 shows a sectional view of the mold of figure 1, during the rubber expulsion phase,

- figure 4 shows a sectional view of a two-half mold provided with sectors according to the present invention, in the closing phase,

figure 5 shows a sectional view of the mold of figure 4, in the loading phase, e

Figure 6 shows a section view of a sliding guide of a sector of the mold of Figure 4 along a ring containing the sectors of the mold itself.

With reference to Figures 4 and 5, a mold cavity 11 and a cylindrical ring 12 for containing a plurality of sectors 17 are defined in a two-half mold provided with sectors, for the production of rubbers by vulcanization, according to the present invention. , said cylindrical ring 12 also being indicated with the term mold casing, a lower plate 13, a lower bead ring 14, an upper plate 15, an upper bead ring 16 and a plurality of sectors 17 (the figure shows a sector 17 on the left and a sector 17 on the right).

The sectors 17 are coupled to the cylindrical ring 12 with the possibility of translation along a conical wall 18, inclined with respect to the direction of mutual movement of the lower plate 13 and of the upper plate 15. The translation of each sector 17 with respect to the cylindrical ring 12 is controlled, during the opening phase of the mold, by a spring 19 which works by compression and pushes on the lower plate 13, and during the closing phase of the mold by the thrust exerted by the upper plate 15.

All the components of the mold (excluding the springs 19) are made of steel for molds, of the same type used for the classic types of mold for solid tires.

The innovation of the proposed solution consists, as shown in Figure 4, in the use of a mold geometry that is absolutely similar (externally) to a classic two-half mold, but characterized internally by different relative movements of the components.

As already mentioned previously, the upward movement of the upper plate 15 and of the upper bead ring 16 allows the spring 19 interposed between the lower plate 13 and the sector 17 to exert its opening force and therefore to allow the sliding of the sector 17 along the conical wall 18 of the circular ring or mold case 12. In particular, the spring 19 is housed in a seat of the sector 17 whose axis is parallel to that of the portion of the conical wall 18 which is located therein radial direction. The end of the spring 19 engages in a seat 20 obtained on the upper surface of the lower plate 13.

Due to the inclination of the conical wall 18 made on the circular ring or mold casing 12, the movement of the sector 17 is not purely vertical (as happens in two-half molds) but has a radial component, which allows easy extraction of the piece , being avoided undercut movements.

To describe in more detail the potential of the mold according to the present invention, the movements carried out and the strengths and criticalities of the proposed solution will be indicated below, step by step, with reference to figures 4 and 5.

In particular, the mold according to the present invention is assembled by the operators in the press as usual, i.e. by fixing the lower plate 13 on the lower press table (not shown), the upper bead ring 16 and the upper plate 15 on the upper press plate ( not shown) and the lower bead ring 14 on the extractor (not shown), coplanar with the lower press table.

In this phase, the springs 19 are slightly in compression, as they must support the weight of the sectors 17. The number of springs 19 for each sector, the stiffness constant of each spring 19, as well as the difference between the rest state and the state of rest maximum compression of the same is calculated on the basis of the width of the tread, the so-called tread drop off (i.e. the semi-difference between the maximum diameter at the center of the tread and the diameter at the outer end of the tread) and therefore the maximum diameter of the raw piece before the insertion on the mold and the start of the vulcanization cycle and the minimum diameter of the tread area, i.e. the diameter measured at the outer side of the tread itself. The number of sectors 17 is mainly a function of the maximum diameter of the cavity 11 of the mold, the weight of the sectors 17 themselves and the number of springs 19 required.

The minimum number of sectors 17 to ensure the good extractability of the rubber is identified in four pieces, to be used for small rubber models (with rim diameter 4 "-8" -9 "), while typically the number of sectors will vary between six and twelve depending on the diameter and complexity of the tread pattern.

A higher number of sectors will have to be considered for particular applications.

The sliding of the sector 17 on the conical wall 18 of the circular ring or mold case 12 is guaranteed by means of a guide 21, equipped with suitable mechanical limit switches designed to prevent the accidental exit of the sectors 17 from the circular ring or mold case 12. The guide 21, characterized by an appropriate but not excessive clearance to avoid possible breakage of the sectors 17 during the closing of the mold, is made in such a way (choice of wear materials and sliding plates) that it does not wear out excessively during use. By way of non-limiting example, the guide 21 can have a prismatic or semicircular conformation. In the example shown with reference to Figure 6, the guide has a T-shaped prismatic conformation.

Referring to Figure 5, with the mold open, the raw material is loaded into the mold itself. In this phase, the useful diameter of the cavity 11 is significantly greater than that of the raw material, thanks to the petal opening of the sectors 17.

Once the raw material has been loaded, the actuation of the closure of the press causes a vertical downward movement of the upper surface of the same and therefore of the upper plate 15 and the upper heel 16 rigidly connected to it. The plate 15, during its descent, will push the sectors 17 downwards, thus generating a sliding phenomenon between the mutually engaged surfaces of the upper plate 15 and the sectors 17. This phenomenon is reduced thanks to the adoption of a special material of sliding placed in correspondence with said mutually engaged surfaces. The rotation of the sectors 17 is prevented by the respective prismatic sliding guides 21.

Once the sectors 17 have reached their abutment, the cavity 11 must be perfectly closed, except for any small clearances foreseen in the design phase or for suitable air / compound vents. The conformation of the mold in closing is shown with reference to figure 4.

From this point on, the vulcanization phase can proceed as for the traditional method. Since the volumes are substantially similar in steel games, it is not necessary to vary the vulcanization cycles due to the effect of different thermal inertias or varied heat sources.

At the end of the vulcanization cycle, what has already been described for the mold closing cycle takes place in reverse form.

The upper plate 15, together with the upper bead ring 16, must rise to allow the "quasi-radial" movement of the sectors 17. Obviously there will always be, due to the imperfect tangentiality between the walls of the mold and the vulcanized compound, a minimum retention effect of the sectors 17 which prevents the mold from opening correctly. However, the action of the springs 19 facilitates and avoids damage to the tread during extraction.

When the mold is fully opened, the radial stroke of the sectors 17 will be sufficient to allow the extraction of the rubber without interference with the mold.

The critical mold design parameters are therefore:

- the number of sectors 17, on which the necessary rubber extraction force depends;

- the radial stroke of the sectors 17, which must be sufficient to allow the extraction of the vulcanized rubber, with the mold open, without interfering with the shape of the tread;

- the vertical stroke of the sectors 17 and the inclination of the conical wall 18, a function of both the radial stroke and the width of the tread, which allows the control of the supporting forces of the sectors 17 and the reaction force applied to the press surface;

- the number of springs 19 and their constructive parameters: the number of springs 19 must be such as to allow the extraction of the rubber, not to excessively decrease the molding pressure and guarantee a residual thrust even when the spring 19 is worn (due to the plastic deformations on the same) (the springs 19 can preferably be of a commercial type to reduce their cost and facilitate their availability / replacement);

- the surfaces of mutual engagement between the sectors 17 and the upper 15 and lower plates 13: the geometric design of these surfaces and their construction must be such as to guarantee a correct hermetic seal of the cavity 11 (unless there is desired play) and therefore avoid the presence of flashes (burrs) in these areas, as the presence of burrs, in addition to being unsightly and requiring further processing, also involves other problems (for example material dispersed on the mold);

- the locking / safety systems of the sectors 17 can be easily disassembled to ensure quick maintenance of the same during cleaning.

The present invention has been described by way of illustration, but not of limitation, according to its preferred embodiments, but it is to be understood that variations and / or modifications may be made by those skilled in the art without thereby departing from the relative scope of protection, as defined from the attached claims.

Claims (4)

CLAIMS 1) Two-half mold comprising a lower plate (13), a lower bead ring (14), an upper plate (15), an upper bead ring (16) and a plurality of sectors (17) which all together define a cavity (11) of the mold, said sectors (17) being coupled to a cylindrical ring (12), arranged externally to them and integral with said lower plate (13), said sectors (17) being free to translate, between two limit switches, with respect to a conical wall (18) of said cylindrical ring (12), with the vertex of the ideal continuation of said conical wall (18) on the side of said lower plate (13), on said sectors (17) acting elastic means (19) which they act on said sectors (17) away from said lower plate (13). 2) Mold with two halves according to claim 1, in which said elastic means are constituted by at least one spring (19) for each sector (17), housed in a seat of said sector (17), with axis parallel to the portion of the wall conical (18) arranged along the same radial direction. 3) Two-half mold according to claim 2, wherein said spring (19) engages in a seat (20) formed on the upper surface of the lower plate (13). 4) Mold with two halves according to any one of the preceding claims, in which a sliding guide (21) is defined between each of said sectors (17) and said conical wall (18) of said cylindrical ring (12).