Background of the invention

[0001] The invention concerns a mold, particularly a mold for press forming doses of plastic material being separated from an extruder.

[0002] Specifically, but not exclusively, the invention can be applied to form plastic caps, for example to close containers.

[0003] The prior art comprises the mold of the figures 1 and 2 being suitable for the compression molding of plastic material doses. This mold of a known type comprises a first half-mold 1 (lower matrix) and a second half-mold 2 (upper punch) being axially movable towards one each other in order to assume at least one open position (not shown) and at least one non-end closed position (figure 1). A tubular element 3 being axially slidable is arranged around the second half-mold 2. In the non-end closed position (closed and filled mold, namely filled with at least one dose), the lower end of the tubular element 3 is contacted with an axial abutment 4 being arranged on the first half-mold 1, the bottom of the forming cavity has a thickness equal to D, the axially movable actuator element 5 which bears the first half-mold 1 is placed at an axial distance equal to E from an abutment of end stop 6 being arranged on the press body 7. In an end closed position (figure 2, closed and empty mold, namely without a dose), the above-mentioned axially movable actuator element 5 has contacted the abutment of end stop 6 and the bottom thickness of the forming cavity has been reduced to a value T2 equal to D - E. The bottom of the forming cavity is delimited above by the lower surface of the second half-mold 2, which is placed at a fixed distance equal to C3 from the abutment of end stop 6. It should be noted that the precision of the value T2 of the thickness dimension of the bottom of the forming cavity, without plastic material dose, also depends on the precision of the above-mentioned distance C3.

[0004] One of the drawbacks of the known mold being described above can be seen when the bottom thickness D of the object to be formed is very thin.

[0005] In this case, the nominal thickness T2 of the forming cavity in the end closed position (closed and empty mold) could be very reduced, for example being of the same order of magnitude of the dimensional tolerances (particularly being bound to the different elastic and/or thermal deformations of the different molds which are usually carried by the press and to the elastic and/or thermal deformation itself of the press complex structure), resulting in a hard contact risk, or in an excessive distance between the "wet" surfaces of the two half-molds being reciprocally facing when the empty mold closes, without plastics, where with wet surfaces it is meant the forming cavity surfaces destined to contact the plastics during the forming phase.

[0006] This hard contact can consist in a real collision between the two half-molds during the closure phase such to cause a considerable damage to the mold.

[0007] The risk is increased when the press is formed by a complex apparatus, such as for example a forming carousel which rotates a plurality of molds, because in this case the precision of the distance T2 with an empty mold would be inevitably very poor as it would depend on a long chain of dimensional tolerances going through the forming carousel, thereby the deviation of the real dimension from the nominal dimension T2, generally different from mold to mold, could be excessive for at least one or more molds, leading to the hard contact.

[0008] Practically, in the compression molding carousel for doses of plastic material of a known type is not possible to mold objects (caps) having a bottom with nominal thickness lower than about 0.2-0.3 millimeters.

[0009] The patent publication US 6736628, referring to the figures 1 to 3, shows a compression mold which comprises a tubular element 57 being axially movable upwards against a spring 74. The compression mold shown by US 6736628, when is closed empty, without plastics, will have to assume a closing position different from the closing position with plastics.

[0010] Generally, in the compression molding, it is the reciprocal movement of the mold parts that transmits the deformation force to the plastic dose to be deformed; this deformation force must be transmitted during all the molding phase, also following the shrinking of the material itself during the molding final phase. For this reason (figure 1) the actuator element 5 will not have to be in abutment (E>0). In the compression molding according to the known art (figure 2), the closing position without plastics is defined by the abutment 6 and thus the gap T2 is affected by a quite "long" kinematic chain.

[0011] Therefore, the compression mold shown by US 6736628 could show the risk of hard contact between the two half-molds during the closure phase without plastics, especially when the bottom thickness of the object to be formed is very thin. All this is not dependent on the dimensional tolerances, whose effect adds to the one just mentioned, and to which deformations caused by thermal components can be added.

[0012] As it will be shown in the following, the solution being the object of the present invention firstly allows reducing the tolerance chain, which affects the definition of the closed mold geometry in a known compression mold, and secondly allows making this tolerance chain substantially not dependent on the press deformation.

[0013] In the present invention, as it can be seen for example in figure 4, now the condition of closed mold without plastics is determined, particularly, by the closure of the first half-mold 1 on the tubular element 3 (abutment 4) and through this on the end stop 8: the gap Tl is determined by the only dimensional tolerances of the elements shown as 1, 2, 3, and the actuator is not abutting (A2>0). Therefore, in any case the condition of closed mold with plastics (figure 3) causes to transmit forces to the plastic (non-abutting actuator, A1>0) with the element 3 in mold closure on the first half-mold 1 (see abutment 4), but not abutting against the second half-mold 2 (B>0).

[0014] Moreover, it should be underlined that the publication US 6736628 shows, referring to figure 4, an injection mold which does not have the spring 74 and, since it is not a compression mold, it is outside the context of the present application. It should be noted that, in an injection mold, the plastic is injected after the mold closure, thereby it is not occurring the situation that on the contrary is typical of a compression mold, where the closure positions with and without plastic are different. Actually, in the injection molding system, the plastic in the fluid state is injected inside the forming cavity when it is already "closed", while in a compression mold - as the one of the present solution - two closed configurations exist, one without plastic and the other with plastic. In the injection mold shown in figure 4 of US 6736628, the mold is closed without plastic and the collar 60 must necessarily contact the cup-shaped element 82 (it cannot be different, since the plastic must be injected in the forming cavity). In the mold of figure 4, a closed position without plastic where the forming cavity volume is less than the closed position with plastic would be unacceptable, because in this closed position with plastic - being purely hypothetical and totally unsuitable - the collar 60 and the element 82 will inevitably loose contact from each other, with the devastating effect of the injected plastic coming out from the forming cavity, which therefore will not be able to be considered as effectively closed. This hypothetical detachment between the collar 60 and the element 82, in the version of figure 4 of US 6736628, will be even more unacceptable because, as it is known, in order to facilitate the air escape, often ventings are made whose dimensions are such to let the air pass through, but not the melted plastic, thereby also a minimal increment of these ventings, due to the detachment of the above-mentioned parts 60 and 82 will be enough to cause the plastic escape. In the present compression mold, as it will be better explained in the following detailed description, the abutment 4 is always contacting the half-mold 1 (see figures 3 and 4 of the present application), preventing the plastic escape, both without plastic and with plastic. This happens also in case ventings are provided for.

[0015] Moreover it should be noticed that in case the thickness of one wall (for example the bottom) of the object to be formed is very thin, the flow sections for the fluid plastic are very narrow, making extremely hard the flow of the plastic itself, thereby the injection molding practically is totally unsuitable to form very thin walls, unless using extremely fluid plastics, resulting in a limitation of the application field.

Summary of the invention

[0016] An aim of the invention is to realize a compression mold being able to solve one or more of the above-mentioned drawbacks of the known art.

[0017] An advantage is to avoid the hard contact between the wet surfaces of the two half-molds also without plastics, where the wet surfaces are surfaces of the forming cavity being intended to contact the plastic during the forming phase.

[0018] An advantage is to avoid the above-mentioned hard contact independently by the elastic and/or thermal deformation of the press structure on which the mold is assembled. Particularly, the above-mentioned hard contact is avoided whichever the elasticity of the press structure is.

[0019] An advantage is that any deformation (thermal and/or elastic) of the press body, or of other elements being external to the mold, will not affect the precision of the dimension defining the thickness of the object wall, particularly because that precision will be depending on a tolerance chain that is internal to each single mold.

[0020] An advantage is to provide a mold being particularly suited for the compression molding of caps for closing containers.

[0021] An advantage is to provide a mold being particularly suited for the compression molding of objects having at least one very thin wall portion, particularly caps having at least one very thin portion of a bottom wall.

[0022] An advantage is that the dimensional tolerance chain, defining the distance precision between two facing mold surfaces without plastics, develops only along dimensions of mold elements, without affecting dimensions of apparatus (press) elements on which the mold itself is assembled.

[0023] An advantage is to make available compensation means being able to obtain the desired thickness of the bottom wall of the molded object even when the mold is supplied with a plastic dose having an insufficient or abundant volume.

[0024] An advantage is to compensate the plastic material shrinking ensuring the transmission of the compression forces even when the bottom wall (that is relatively thin) of the object in the forming cavity is already solidified.

[0025] An aim of the invention is to realize a plastic element having at least one weak portion, which can be opened by fracture, for example a fracture caused by a pull, tear, push force, etcetera.

[0026] An advantage is to have an element, for example a cap to close containers, with at least one wall provided with one or more facilitated fracture weak areas, each comprising a continuous material membrane.

[0027] An advantage is to provide one or more facilitated fracture weak areas, each being made of a continuous material membrane.

[0028] An advantage is to form weak areas that do not have discontinuities in the material flow lines.

[0029] An advantage is that the mechanical characteristics of the material in the weak areas are uniform and little sensitive to thermal and/or aging phenomena.

[0030] An advantage is to avoid the development of plastic material splinters during breaking phase of the weak portion.

[0031] Those and more aims and advantages are obtained by a mold or by a plastic element according to one or more claims mentioned below.

[0032] In one example, a mold to compression form plastic material doses, particularly to form elements having at least one facilitated fracture thin wall, comprises two half-molds (die and punch), which are axially movable towards each other, and a tubular element, which is axially slidable around one of the two half-molds, the mold being able to assume an end closed position, without dose, wherein the tubular element is arranged contacting an axial abutment of one half-mold at one side and an axial end stop of the other half-mold at the other side, with the purpose of preventing the hard contact between the half-molds.

[0033] In one example, a plastic element comprises a body made by compression molding plastic material in a single piece, wherein the body comprises at least one facilitated fracture portion formed by a continuous membrane.

Brief description of the drawings [0034] The invention will be better understood and carried out referring to the attached drawings, which illustrate some non-limiting carrying out examples thereof.

[0035] Figure 1 is a vertical elevation cross-section of a mold of a known type in a closed configuration with plastic dose. Figure 2 shows the mold of a known type of figure 1 in a closed configuration without plastic dose. Figure 3 is a vertical elevation cross- section of a first example of a mold according to the invention in a closed configuration with plastic dose. Figure 4 shows the mold of figure 3 in a closed configuration without plastic dose. Figure 5 is a vertical elevation cross-section of a second example of a mold according to the invention in a closed configuration with plastic dose. Figure 6 shows the mold of figure 5 in a closed configuration without plastic dose. Figure 7 is a vertical elevation cross-section of a third example of a mold according to the invention in a closed configuration with plastic dose. Figure 8 shows the mold of figure 7 in a closed configuration without plastic dose. Figure 9 is a vertical elevation cross-section of a fourth example of a mold according to the invention in a closed configuration with plastic dose. Figure 10 shows the mold of figure 9 in a closed configuration without plastic dose. Figure 11 is a vertical elevation cross-section of a fifth example of a mold according to the invention in a closed configuration with plastic dose. Figure 12 shows the mold of figure 11 in a closed configuration without plastic dose. Figure 13 is a top view of a body obtainable with a mold realized according to the invention. Figure 14 is the XIV-XIV cross-section of figure 13. Figure 15 is a top view of another body obtainable with a mold realized according to the invention. Figure 16 is the XVI- XVI cross-section of figure 15. Figure 17 is a top view of yet another body obtainable with a mold realized according to the invention. Figure 18 is the XVIII- XVIII cross-section of figure 17. Figure 19 is a top view of a further body obtainable with a mold realized according to the invention. Figure 20 is the XX-XX cross-section of figure 19. Figure 21 is a top view of a container closure cap obtainable with a mold realized according to the invention. Figure 22 is the XXII- XXII cross-section of figure 21. Figure 23 is a top view of a drip-feed element obtainable with a mold realized according to the invention. Figure 24 is the XXIV-XXIV cross-section of figure 23. Figure 25 is a top view of another drip-feed element obtainable with a mold realized according to the invention. Figure 26 is the XXVI- XXVI cross-section of figure 25. Figure 27 is the XXVII-XXVII cross-section of figure 25. Figure 28 is a top view of a container-closing element obtainable with a mold realized according to the invention. Figure 29 is the XXIX-XXIX cross-section of figure 28. Figure 30 is a lateral view from top of figure 28.

Detailed description

[0036] In this description, similar elements being in common with different mold examples illustrated in the figures 1 to 12 have been shown with the same numbers and similar elements being in common with different examples of cap bodies illustrated in the figures 13 to 30 have been shown with the same numbers.

[0037] Referring to the figures 3 and 4, it is illustrated a mold example for compression molding doses of plastic material according to the invention. The mold comprises a first (lower) half-mold 1 and a second (upper) half-mold 2 being axially movable (with vertical X axis) towards each other in order to assume an open position (not shown) in which it is possible to insert at least one dose of plastic material (coming from an extruder) between the above-mentioned half-molds and a non-end closed position (figure 3) or closed position with dose, in which the dose of plastic material (in the pasty state) can be pressed in a cavity at least partially delimited by the above-mentioned half- molds.

[0038] The first half-mold 1 has a first surface (being perpendicular to the axis and facing upwards) which delimits the bottom of the forming cavity on one side (below). The second half-mold 2 has a second surface (being perpendicular to the axis and facing downwards) which delimits the bottom of the forming cavity on one side on the opposite side (above). The first (flat) surface and the second (flat) surface are axially facing to each other (in parallel).

[0039] The first half-mold 1 may comprise, for example, a die. The second half-mold 2 may comprise, for example, a punch.

[0040] In the specific case, the axial opening and closing movement of the mold is provided to the first (lower) half-mold 1 by means of an actuator element 5, for example the movable element of a (vertical axis) linear actuator. The linear actuator may be arranged on a forming apparatus (for example on a body of a press 7) to which the mold is operationally associated.

[0041] The mold comprises a tubular element 3 being axially movable. The movable tubular element 3 may be arranged, like in this example, around the second half-mold 2. Particularly, the movable tubular element 3 may be axially slidable with respect to the first half-mold 1 and/or with respect to the second half-mold 2. Particularly, the movable tubular element 3 may be slidingly coupled with an external surface of the second half- mold 2. Particularly, the movable tubular element 3 may be supported by the second half- mold 2.

[0042] With the closed mold, particularly when the first and the second half-mold 1 and 2 are in the non-end closed position (figure 3, closed mold with dose), the tubular element 3 may partially delimit the forming cavity. When the first and second half-mold 1 and 2 are in the non-end closed position (closed mold with dose), the tubular element 3 may be arranged contacting an axial abutment 4 being arranged on the first half-mold 1. Particularly, during the mold closure phase (reciprocal approaching of the half-molds 1 and 2, for example the movable first half-mold 1 rising towards the fixed second half-mold 2 which bears the tubular element 3), the axial abutment 4 (facing upwards) of the first half- mold 1 will be able to meet and contact the first (lower, facing downwards) end of the tubular element 3.

[0043] The mold may assume an end closed position (figure 4, closed mold without dose) or closed position without dose, wherein the cavity volume defined between the half- molds 1 and 2 is lower than the above-mentioned non-end closed position.

[0044] In the end closed position (without dose) the tubular element 3 may contact the above-mentioned axial abutment 4 from one side (first end, particularly the lower one) and an axial end stop 8 (facing downwards) being arranged on the second half-mold 2 on the opposite side (second end, particularly the upper one, facing upwards).

[0045] The end closed position (without dose) may be defined, particularly, by the positions of the abutment 4 and end stop 8. When the first half-mold 1 and the second half- mold 2 are in the end closed position (figure 4), the cavity may be delimited by the two above-mentioned first and second (flat) surfaces, one of the first half-mold 1 and the other of the second half-mold 2, being axially facing with each other and spaced at a minimum distance Tl from each other.

[0046] This minimum distance Tl may be, for example, less than 0.4 millimeters or less than 0.3 millimeters or less than 0.2 millimeters, particularly between 0.005 and 0.3 millimeters or between 0.01 and 0.2 millimeters or between 0.02 and 0.1 millimeters.

[0047] In the non-end closed position (figure 3), the tubular element 3 may be, like in this case, (with the second end) at an axial distance equal to B from the above-mentioned axial end stop 8. In the non-end closed position, the two first and second wet surfaces facing to each other may be at a reciprocal minimum axial distance equal to D. This distance D substantially corresponds to the thickness of the bottom wall of the object in the forming cavity. In the non-end closed position, the bottom of the cavity, that is the first (horizontal) surface of the first half-mold 1, may be at an axial distance equal to CI from the above-mentioned axial end stop 8 being arranged on the second half-mold 2. In the non-end closed position, the axially movable actuator element 5 which carries the first half-mold 1 may be placed at a distance equal to Al from an abutment of end stop 6 (being arranged on the press body 7).

[0048] In the end closed position (figure 4), the tubular element 3 may be, as said, (with the upper second end) contacting the above-mentioned axial end stop 8. In the end closed position, the two first and second surfaces facing to each other may be, as said, at a reciprocal minimum axial distance equal to T1=D-B. This distance Tl substantially corresponds to the thickness of the cavity in the extreme situation of minimum volume of the empty cavity, namely without plastic material. In the end closed position, the bottom of the cavity, that is the first surface of the first half-mold 1 which delimits the mold cavity at the bottom, may be at an axial distance equal to C2=C1-B from the above-mentioned axial end stop 8 being arranged on the second half-mold 2. In the end closed position, the axially movable actuator element 5 which carries the first half-mold 1 may be placed at an axial distance equal to A2=A1-B from the above-mentioned abutment of end stop 6 (being arranged on the press).

[0049] In order to form objects having a very thin bottom wall (for example having a nominal thickness of about 2 hundredths of millimeter), a high precision will have to be ensured of the distance Tl, that is the distance between the two first and second surfaces of the two half-molds 1 and 2, axially facing to each other, that is the two wet surfaces (perpendicular to the X axis of the mold) which delimit the thickness of the object bottom wall during the forming phase.

[0050] In the specific case, the distance Tl precision depends on dimensional tolerances of elements all belonging to the mold and not on elements of the press body 7 or anyway on elements external to the mold. Particularly, the distance Tl precision will depend on the precision being used to realize the first half-mold 1 (particularly the axial distance between the first surface and the axial abutment 4 contacting the lower first end of the tubular element 3), the second half-mold 2 (particularly the axial distance between the second surface and the axial end stop 8 contacting the upper second end of the tubular element 3) and the movable tubular element 3 (particularly the axial distance between the lower first end and the upper second end). Therefore, the distance Tl precision will be a function of a tolerance chain being internal to each individual mold. Practically, any (thermal and/or elastic) deformation of the press body 7 or of other elements being external to the mold, will not affect the dimension Tl precision.

[0051] As said, one of the two half-molds, for example the first half-mold 1, may be carried by a movable actuator element 5 of a (vertical axis) linear actuator. This movable actuator element 5 may have a protruding portion 9 which may be distant (at the distance A2) from the above-mentioned actuator axial abutment of end stop 6, when the first half- mold 1 and the second half-mold 2 are in the end closed position (without dose).

[0052] When the first half-mold 1 and the second half-mold 2 are in the end closed position, the tubular element 3 may partially delimit the mold cavity. When the first half- mold 1 and the second half-mold 2 are in the non-end closed position, the tubular element 3 may partially delimit the mold cavity.

[0053] The mold non-end closed position may be assumed, particularly, with the at least one dose of plastic material inside the mold cavity. The mold end closed position may be assumed, particularly, without the plastic material inside the mold cavity.

[0054] Referring to the figures 5 and 6, the mold may comprise compensation means partially delimiting the cavity when the first half-mold 1 and the second half-mold 2 are in the end closed position (without dose, figure 6) and in the non-end closed position (with dose, figure 5).

[0055] Particularly, the compensation means may comprise at least one element being axially movable so to vary the cavity volume. In the specific case, the compensation means comprises a tubular body 10 being slidingly coupled with the tubular element 3 and/or with the second half-mold 2. Particularly, the compensation means may be between the tubular element 3 and the second half-mold 2. Particularly, the compensation means may comprise elastic means 11 being arranged in order to push the tubular body 10 against an abutment 12 being arranged on the tubular element 3. The elastic means 11 may be arranged between the second half-mold 2 and the axially movable tubular element 3. In the non-end closed position (mold with dose), the action of the plastic material pressing in the cavity against the elastic means 11, will cause the tubular body 10 to be placed at an axial distance G from the abutment 12 (figure 5).

[0056] The compensation means allows obtaining a specific volume of the bottom wall of the molded object also when the mold is supplied with a plastic dose of insufficient volume. [0057] Particularly, the compensation means allows compensating the shrinking of the plastic material ensuring the transmission of the compression forces also when the bottom wall of the object in the forming cavity (which can solidify quickly since it is relatively thin) is already solidified.

[0058] The compensation means may delimit an (annular) area of the forming cavity (far from the bottom of the cavity, particularly a cavity area where an end annular area of a lateral tubular portion of the object to be molded is formed, for example a cap) therefore, due to the compensation means mobility, that cavity area has a variable geometry.

[0059] During the forming phase, the pasty plastic material, which is in this cavity area, due to the compression force between the two half-molds 1 and 2, exerts a pushing action against the compensation means (opposing the action of the elastic means 11). The compensation means action avoids the development of defects in the formed object, particularly in the above-mentioned cavity area where they operate.

[0060] Referring to the implementation examples being illustrated in the figures 7 to 12, at least one of the two reciprocally facing first and second surfaces may have one or more areas 13 being shaped and arranged to form reduced thickness wall portions and other areas 14, being adjacent to the above-mentioned areas 13, being shaped and arranged to form wall portions having greater thickness. These reduced thickness wall portions may be placed at the above-mentioned minimum distance Tl. These thinner portions, having a reduced thickness, adjacent to the thicker wall (bottom) portions of the product, may have the function of forming one or more facilitated fracture weak areas or portions (for example fracture by traction and/or torsion and/or compression, particularly fracture by tear, piercing, pushing, etcetera), of a (bottom) wall of the finished product. Particularly, these weak portions (breakable, pierceable, tearable, removable, etcetera) may be useful to define opening areas.

[0061] Particularly, the area 13 may be disc- shaped, like in the example of figures 9 and 10. The area 13 may be useful to form a lowered central portion of the bottom wall of the object. This central (disc-shaped) portion may be easily pierced since its thickness is much reduced.

[0062] Particularly, the area 13 may be shaped as a (continuous or dashed) line to form thin wall portions linearly extended, or the area 13 may form one or more spots spaced from each other. This area 13 may be arranged, for example, along a circumference (for example having the center on the X axis). The area 13 may have a triangle-shaped cross-section (like in the example of figures 7 and 8) or a trapezoid- shaped one (like in the example of figures 11 and 12).

[0063] The above-described compensation means may be also associated with implementation examples like the ones illustrated in figures 7 to 12.

[0064] Moreover, a compression molding apparatus for plastic material doses is described but not illustrated. This forming apparatus comprises at least one revolving carousel supporting at least one mold being arranged in order to receive plastic material doses being separated by an extruder, particularly a plurality of molds being angularly arranged apart from each other, wherein each mold is realized according to the present invention. This forming apparatus may comprise at least one extruder (of a known type) and means (of a known type) for separating the plastic material doses from the extruder. The separating means may comprise at least one revolving carousel carrying at least one separating member. The apparatus may also comprise means (of a known type) for transferring the separated dose from the extruder to the mold.

[0065] During usage, at least one dose of melted plastic material is separated from one outlet of the extruder and it is transferred inside the mold in open position. Then, the mold is closed, for example by rising the lower first half-mold 1 which will approach the upper second half-mold 2, until reaching the non-end closed position (figure 3 or 5 or 7 or 9 or 11). In this position, the thickness of the bottom wall of the object (cap) will be equal to D. This thickness generally will be greater than the dimension Tl of the cavity with the empty closed mold without dose, thereby the second end of the tubular element 3 should not abut against the end stop 8 being placed on the second half-mold 2. Generally, it will be possible to mold objects having a bottom wall thickness greater than Tl, without the risk of hard contact between the first surface of the first half-mold 1 and the second surface of the second half-mold 2, a part from dimensional tolerances also accounting for construction errors and any elastic and/or thermal deformation of the mold elements. Any elastic and/or thermal deformation of elements of the thermoforming apparatus that are external to the mold will not affect the dimensional precision of the mold end closed position.

[0066] The figures 13 to 20 illustrate molded bodies or elements being realizable using the molds of figures 3 to 12. In the examples illustrated here, the lateral tubular wall of the molded product is vertical. It is possible to consider other examples where the molded product has a (outwardly) tapered lateral wall, or yet other shapes.

[0067] Referring to the figures 21 to 30, there are shown other body or element examples being realizable using molds according to the invention.

[0068] As said, the molded products may be particularly useful to form several types of plastic elements such as, for example, containers closing caps having a weakened line (for example in order to remove a safety lock device, like in the example of figures 21 and 22), container elements having a pierceable portion (for example for drip-feeds or the like, like in the examples of figures 23 to 27, container closures having a removable portion (for example closures being associable with a container body, like in the example of figures 28 to 30), other cap types having a weak portion (particularly having an opening portion being breakable, pierceable, tearable, etcetera), for example caps having a function as casing, covering, container, etcetera.

[0069] Each molded element may comprise a rigid body. Particularly, each molded element may be realized in a single piece by compression molding a plastic material. The plastic material of the molded product may comprise, for example, at least one material selected from: polyolefins, polyesters, polyamides, polysaccharides, among which for example HDPE, PP, LDPE, PET, PLA, PBT, PEF, nylon, cellulose, and combinations or mixtures of the above-mentioned materials.

[0070] Each body may have a (bottom) wall which may comprise, particularly, at least one weak portion 15 (or a portion being breakable, openable, pierceable, etcetera) having a smaller thickness (being obtained in the mold at the areas 13) and at least one bearing portion 16 having a greater thickness (being obtained in the mold at the areas 14). Particularly, the weak portion 15 may comprise a membrane portion, for example a continuous membrane (free of through-holes or other through discontinuities interrupting the membrane wall).

[0071] The weak portion 15 may be at least partially breakable by means of a pull force, for example being exerted by an operator manually pulling a tongue or other grip element in order to tear the weak portion 15, or by means of a push force, for example a pressure being exerted by a push element (for example a piercing solid body, such as a spout or a syringe, or a fluid under pressure) which pushes to break the weak portion 15. The different embodiments being illustrated differ from each other in the different shape and arrangement of the weak portions 15, namely of the body areas which are intended to fracture.

[0072] The bearing portion 16, for example, may have a maximum thickness that is more than double, or more than triple, or more than quadruple, or more than quintuple, with respect to a minimum thickness of the weak portion 15.

[0073] Particularly, the weak portion 15 may have at least one thickness less than 0.4 millimeters, or less than 0.3 millimeters, or less than 0.2 millimeters, for example between 0.005 and 0.3 millimeters, or between 0.01 and 0.2 millimeters, or between 0.02 and 0.1 millimeters, or equal to 0.020 + 0.015 millimeters.

[0074] As in these examples, the body may have a lateral wall 17 extending from a (peripheral) edge of the bottom wall. As in these examples, the body may have one upper opening (which could be intended to be closed or sealed) delimited by an edge of the lateral wall 17.

[0075] In the examples being illustrated here from figure 13 to figure 20, the lateral wall 17 of each body has a cylinder shape. However, it is possible to envision that the cap body may have a lateral wall having a different shape, for example a tapered (cone frustum) shape, for example having an upper opening diameter greater than the bottom wall diameter, or having a shape outwardly rounded in the middle, or having a shape inwardly receding in the middle, or having yet another shape.

[0076] The molded product shown in figures 21 and 22 is a single piece body that forms a container cap wherein the weak portion 15 comprises a facilitated fracture line defining a safety ring being removable by tearing.

[0077] The molded product shown in figures 23 and 24 is a single piece body that forms a closing element for a drip-feed wherein the weak portion 15 comprises a discshaped (annular) wall defining a pierceable membrane, for example by a drip-feed cannula or syringe.

[0078] The molded product shown in figures 25 to 27 is a single piece body that forms another closing element for a drip-feed wherein the weak portion 15 comprises a pair of disc-shaped walls defining two pierceable membranes, for example by a drip-feed cannula or syringe.

[0079] The molded product shown in figures 28 to 30 is a single piece body that forms a closing element being associable to a container wherein the weak portion 15 comprises a facilitated fracture line defining a closing wall removable by tearing to allow pouring the contents outside the container.

[0080] Each above-describe molded body may be manufactured by means of a mold realized according to the present invention, for example one of the above-described molds, having a forming cavity of the proper shape. [0081] The body is entirely obtained by compression molding a plastic material (particularly without any following machining causing material deformation or removal, for example incisions or cuttings, with the purpose of forming the weak areas intended to fracture). Hence, the openable areas, namely the weak portions 15 (in the form of continuous membranes), are directly obtained in the compression molding phase. Due to that, the weakened areas do not have discontinuities in the material flow lines (as for example it would happen in case of a mechanical machining following the molding) and therefore the material mechanical characteristics are more even and additionally they are less sensitive to thermal and/or aging phenomena.

[0082] Moreover, it has been observed that the openable areas being formed by the weak portions 15 have such characteristics to avoid or reduce the risk of developing small splinters of plastic material when fracturing the portions 15 themselves.