Patent Application
20070292554
The invention relates to apparatuses and a method for forming, particularly by injection-moulding or compression-moulding, objects made of plastics. The apparatuses and the method according to the invention are particularly suitable for producing caps for containers and bottles, heads of tubes for packaging and preforms for bottles made, for example, of polyethyleneterephthalate (PET).
Italian patent application RM 2002A000099 discloses an apparatus for producing, by compression-moulding, preforms in plastics, for example PET, to be used in the blowing of bottles. The apparatus comprises a carousel that is rotatably movable around a vertical axis and is peripherally provided with a plurality of moulds. Each mould comprises a die and a punch that is movable in relation to the die in a vertical opening direction. The punch can move between an opening position in which between the die and the punch it is possible to introduce a dose of plastics to be formed, and a closing position in which the punch engages with the die, defining a forming chamber inside which the preform is formed.
The die comprises a fixed part connected fixedly relative to the carousel and suitable for shaping a portion of substantially cylindrical preform from which the body of the bottle will be subsequently obtained by blow-moulding. The die furthermore comprises two movable elements suitable for externally shaping the neck of the preform, which is provided with a threaded portion and with a collar provided with undercuts. The movable elements each have a “C”-shaped portion internally provided with a forming surface suitable for obtaining the neck of the preform from a part of the dose, and having an end fixed relative to a lever. The levers are in turn hinged on a column parallel to the opening direction of the mould and can rotate on a plane orthogonal to the opening direction between a disengagement position in which the movable elements are spaced from one another and a contact position in which the movable elements are in contact with one another in such a way as to define a portion of the forming chamber. In order to keep the radial overall dimensions of the carousel on which the moulds are assembled limited, the length of the levers is rather reduced, i.e. the “C”-shaped portions of the movable elements are near the column.
The latter is slideable parallel to the opening direction of the mould between an upper position, in which the movable elements are at a certain distance, measured parallel to the opening direction on the fixed part of the die, and a lower position in which the movable elements are in contact with this fixed part.
At the start of the forming phase, a dose of plastics is introduced into the fixed part of the die. The punch is located in the opening position, the movable elements are arranged in the disengagement position and the column is in the upper position in which the movable elements are kept far from the fixed part of the die. Subsequently, a cam mechanism moves the movable elements from the disengagement position to the contact position, after which the column moves to take the movable elements to the lower position in contact with the fixed part of the die. Also the punch moves parallel to the opening direction until reaching the closing position in which forming of the preform occurs. At the end of the forming phase, the operations disclosed previously have to be performed again in reverse order.
A drawback of the mould disclosed in RM 2002A000099 is that relatively long strokes are necessary to move the movable elements from the contact position to the disengagement position so as to be able to extract a preform from the mould. The movable elements in fact have to rotate in relation to one another by an angle of significant amplitude in order that the ends of the “C”-shaped portions that are fixed relative to the lever move away from one another by an amount such as to enable the undercuts formed on the neck of the preform, and in particular the collar, to be completely disengaged from the movable elements.
Furthermore, in the mould disclosed in RM 2002A000099 it is necessary to provide a first driving mechanism, normally of hydraulic type, to move the punch between the opening position and the closing position and a second driving mechanism, comprising the column and the cam mechanism and arranged outside the punch and the die, to move the movable elements. This significantly complicates the structure of the apparatus. Furthermore, it is not always easy to manage the first and second driving mechanism in a coordinated manner so as to move the punch and the movable elements with precision and according to a preset sequence.
The doses of plastics that are introduced inside the mould may have a weight, and therefore a volume, that is slightly variable between one dose and the next. There is thus the risk of obtaining variations in the dimensions of the moulded objects as the weight of the dose varies, which may not be acceptable.
A mould is known for obtaining by compression-moulding a head that is suitable for being joined to a tubular body so as to form a tube for toothpaste or other paste-like substances. The head comprises a frustum-conical portion from which an externally threaded neck extends. The known mould comprises a die suitable for forming the external surface of the frustum-conical portion and the threaded surface of the neck, and a punch cooperating with the die to form the internal surface of the head. The punch and the die are movable in relation to one another between an opening position in which they are arranged at a certain distance from one another to receive a dose of plastics, and a closing position in which they interact to form the head. The die comprises a plurality of sectors that are movable away from one another to disengage from the threaded neck of the head. At the end of the forming phase, after the punch has moved away from the die, the sectors that compose the die move away from one another, disengaging the head, which falls through gravity onto a collecting surface underneath.
The ways of falling of the head onto the collecting surface are practically uncontrolled and the heads may get arranged on the collecting surface with different orientations and in undesired positions. It is therefore necessary to provide, downstream of the mould, orientation devices that arrange the heads in an ordered position in such a way that subsequent control and viewing devices can monitor correctly the quality of the obtained heads.
An object of the invention is to improve the apparatuses and the methods for forming objects, particularly by means of compression- or injection-moulding of plastics.
A further object is to provide apparatuses for forming an object that are provided with movable elements for disengaging from the formed object with shorter strokes in relation to the known apparatuses.
A still further object is to provide apparatuses for forming an object that are provided with movable elements for disengaging from the formed object, in which the movable elements can be driven more simply in relation to the known apparatuses.
Another object of the invention is to provide apparatuses that are able to form objects provided with good dimensional precision even when they are obtained from doses of variable weight.
Still another object of the invention is to provide apparatuses and methods that enable the formed objects to be removed from the mould in controlled conditions and to be deposited on a collecting surface in a desired orientation.
In a first aspect of the invention, there is provided an apparatus comprising forming means closable in a direction to form an object, said forming means comprising at least two reciprocally movable elements along respective arched trajectories to disengage from said object, characterised in that said arched trajectories have respective components parallel to said direction.
Owing to this aspect of the invention, an apparatus is obtained in which the movable elements disengage from the formed object, performing relatively limited strokes.
For example, if the apparatus comprises a plurality of forming means assembled peripherally on a carousel rotatable around an axis parallel to the aforementioned direction, the arched trajectories of the movable elements can extend around a point arranged in a position relatively far from the object being formed, without causing an unacceptable increase of the radial dimensions of the carousel. This enables the angular shifts of the movable elements to be limited.
Furthermore, the movable elements can start to disengage from the formed object whilst the forming means is opening, which results in an increase in productivity.
In a second aspect of the invention, there is provided an apparatus comprising forming means closable in a direction to define a forming chamber having a portion provided with a transverse dimension extending transversely to said direction and adjacent to a further portion of lesser transverse dimensions in relation to said transverse dimension, said forming means being decomposable into a first part and at least two movable elements in relation to said first part, characterised in that said at least two movable elements are positionable in relation to said first part in such a way that said portion is defined by adjacent zones of said at least two movable elements and of said first part.
Owing to the second aspect of the invention, an apparatus is obtained that is provided with movable elements that can be moved away from one another to disengage from a formed object, performing strokes of limited extent. The transverse dimension of the forming chamber measured transversely to the closing direction of the forming means, which in the particular case of forming preforms is the same as the diameter of the collar, is in fact jointly defined by the movable elements and by the first part of the forming means and as such does not give rise to undercuts on the formed object. To extract from the forming means the portion of forming chamber having such a transverse dimension, it is thus necessary to move away the movable elements from one another by a quantity that is less than the stroke that would be required if the portion were entirely defined by the movable elements, as occurs in RM 2002A000099.
In a third aspect of the invention, there is provided an apparatus comprising forming means partially included in a casing and closable in a direction to form an object, said forming means comprising at least two movable elements that are drivable by moving means along respective trajectories having a transverse component in relation to said direction to disengage from said object, characterised in that said moving means is assembled in said casing.
Owing to this aspect of the invention, an apparatus having a particularly simple structure is obtained. The moving means assembled on the casing of the forming means has limited overall dimensions and can be managed in a simpler manner in relation to the case in which the moving means is totally outside the forming means.
Furthermore, by assembling the moving means in the casing in which the forming means is partially housed, it is possible to move the forming means, together with the movable elements and the corresponding moving means, along a preset path inside the apparatus. In particular, this path may extend across a plurality of carousels, so as to increase the time available for introducing the dose into the forming means.
In a fourth aspect of the invention, there is provided an apparatus comprising first forming means and second forming means suitable for interacting in a closing position to define a chamber for forming a dose of plastics, said second forming means comprising a first member suitable for coming into contact with said first forming means and a second member, characterised in that in said closing position said second member is movable in relation to said first forming means by elastic means to vary the volume of said chamber according to the weight of said dose.
Owing to the fourth aspect of the invention, it is possible to obtain objects provided with high dimensional precision, even when doses of plastics are processed that have even small weight variations.
In a fifth aspect of the invention, there is provided an apparatus comprising forming means and forming and compensator means, suitable for interacting in a direction to define in a closing position a chamber for forming a dose of plastics, said chamber having a maximum longitudinal dimension in said direction, characterised in that said forming and compensator means are positionable in relation to said forming means in such a way as to define a dimension of said chamber in said direction, different from said maximum longitudinal dimension, substantially independent of the weight of said dose.
Owing to the fifth aspect of the invention, it is possible to obtain objects provided with great dimensional precision even when doses of plastics having weight variations have to be processed. The configuration of the forming means and compensators in fact enables the position of an end wall of an object to be formed to be altered without varying the distance between respective active surfaces of the forming means, which determine a thickness of the object. It is thus possible to keep constant the thickness between an object formed in a given pressing cycle and that of a subsequent pressing cycle in zones of these objects in which it is desired to obtain great dimensional precision.
In a sixth aspect of the invention, there is provided an apparatus comprising punch means and die means suitable for interacting to form an object, characterised in that it furthermore comprises centring means suitable for engaging with a portion of said object to support said object when said punch means and said die means disengage from each other.
In a seventh aspect of the invention, there is provided a method comprising forming an object by punch means and die means, spacing said die means and said punch means away from said object, characterised in that, during said spacing, there is provided supporting said object.
The apparatus and the method according to the sixth and seventh aspect of the invention enable the object to be kept in a controlled position whilst the punch means and the die means disengage from the formed object. In this way the formed object is prevented from being released in undesired positions or falling onto a collecting surface underneath with unwanted orientations. Any orientation devices arranged downstream of the punch means or of the die means are therefore superfluous.
The invention can be better understood and implemented with reference to the attached drawings, which illustrate some embodiments thereof by way of non-limitative example, in which:
a is a partially sectioned enlarged and fragmentary schematic view of two movable elements kept in contact by a ring element;
With reference to FIGS. 1 to 4 there is shown a mould 1 of an apparatus for forming preforms 4 by compression-moulding of a plastics material, for example polyethyleneterephthalate (PET). The preforms 4 formed in the mould 1 can be subsequently used to obtain bottles by means of blow-moulding.
The apparatus may comprise a plurality of moulds 1 arranged peripherally on a carousel rotatable around an axis in such a way that each mould 1 describes a circular trajectory during rotation of the carousel. Along the circular trajectory each mould 1 is placed in an opening position in which a dose of plastics to be formed is introduced inside it. Subsequently, the mould 1 is closed by pressure to form the dose so as to obtain a preform 4, which remains in the closed mould for a sufficient time to ensure its stabilisation and cooling. The mould 1 is then opened again to extract the finished preform 4 and a new dose of plastics to be formed is introduced therein.
The mould 1 comprises forming means closable in a direction A to form a preform 4 from a dose of plastics in a viscous liquid state (more or less viscous). The forming means comprises a punch 3 that reproduces the internal shape of the preform 4 and die means 2 that is decomposable into a first part 52 in which a recess 5 is obtained and into a pair of movable elements 7. In the recess 5 a substantially cylindrical external surface 6 of the preform 4 is shaped, whereas the movable elements 7 form a threaded portion 8 of the preform 4. During the subsequent process of blow-moulding of the preforms 4, the threaded portion 8 does not undergo substantial shape variations.
The die means 2 is movable in relation to the punch 3 in the direction A between a closing position, shown in
In the opening position the die means 2 is on the other hand far from the punch 3, so that the preform 4 can be extracted from the mould 1.
The movable elements 7 are reciprocally movable, owing to moving means 53, between a contact position, shown in
As shown in FIGS. 2 to 4, the moving means 53 comprises two crosspieces 13, each connected to a respective movable element 7 by a pair of columns 12, provided below with respective shanks 10. The columns 12 are movable in motion of translation in the direction A to move the movable elements 7 between a lower position, shown in
Each movable element 7 is driven between the lower position and the upper position by a respective actuator 14, for example of the pneumatic type, from which a stem 15 protrudes on which a head 16 is fitted that engages in a hollow 17 obtained on the crosspiece 13.
Each actuator 14 is assembled on an end of a support element 28 provided with an intermediate portion fixed by a screw 29 to a pivot 11 extending along an axis X, perpendicular to the direction A. On the support element 28, a lever 21 is obtained that extends transversely in relation to the stem 15 in such a way as to give the support element 28 an “L” shape. The lever 21 projects towards the outside of the casing 27 through a passage 30 and is drivable by a driving device of known type that is not shown, for example a cam or a system of the rod/tappet type.
As shown in
The movement of the movable elements 7 along the arched trajectory enables even objects to be extracted from the mould 1 that are provided with external undercuts such as threads on the threaded portion 8 of the preform 4 or a collar 22 provided in the joint zone between the external surface 6 and the threaded portion 8 of the preform 4. To do so, limited rotations of the movable elements 7 are necessary. In fact, the pivots 11 around which the movable elements 7 rotate can be positioned at a relatively great distance from the movable elements 7 without influencing the radial dimensions of a possible carousel on which the moulds 1 are assembled. This enables the movable elements 7 to move away from one another by the distance required to extract the preforms 4, without, however, performing very large rotations.
As shown in
This conformation of the movable elements 7 and of the first part 52 enables the stroke of the movable elements 7 that is required to extract the preform 4 from the mould 1 to be reduced. As in fact the surfaces of the mould 1 that shape the collar 22 belong to distinct parts that are movable in an independent manner, the collar 22 does not define an undercut on the mould 1.
Above the movable elements 7, a ring element 25 is provided that is shown in
In an alternative embodiment, shown in
The mould 1 furthermore comprises an aligning device, shown in detail in
In the disengagement position of the movable elements 7, shown in
With the mould 1 cooling means is associated comprising a refrigerant fluid circulating in a cooling circuit so as to reduce the temperature of the preform 4 that has just been formed. In particular, the refrigerant fluid reaches the movable elements 7 by means of conduits obtained inside the columns 12 and communicating with further conduits obtained in the crosspieces 13. The latter are provided with threaded holes 38, shown in
During operation, a preform 4 is formed from a dose of plastics during a forming phase in which the die means 2 and the punch 3 are in the closing position, as shown in
The mould 1 remains in this configuration even in a subsequent stabilisation and cooling phase, in which the preform 4 is cooled owing to refrigerant fluid circulating in the movable elements 7 and outside the first part 52 of the die means 2.
At the end of this phase, the die means 2 moves downwards in the direction A to move away from the punch 3. The ring element 25 moves fixedly relative to the die means 2 by keeping the movable elements 7 in the contact position. In this position, the movable elements 7 are firmly tightened on the threaded portion of the preform 4, which detaches itself from the punch 3. Subsequently, the ring element 25 stops its stroke, whilst the die means 2 continues to move away from the punch 3 moving in direction A. The further frustum-conical surfaces 55 thus detach themselves from the frustum-conical surface 54 and the ring element 25 stops interacting with the movable elements 7.
As shown in
At this point, the levers 21 are rotated around the respective X axes and move the movable elements 7 to the disengagement position in
When the preform 4 has been extracted from the recess 5, the levers 21 are released and the traction springs 20 return the movable elements 7 to the contact position. At this point, the columns 12, through the action of the force of gravity and/or of the actuators 14, move the movable elements 7 to the lower position and it is possible to start a new forming cycle. During this phase, the aligning device prevents corresponding shifts of the movable elements 7.
Compensating means of the known type can be associated with the mould 1 to take into account variations in the weight of successive doses.
The movable elements provided with moving means assembled in the casing that houses the recess 5 define forming units that are particularly suitable not only for being assembled on a rotating carousel, but also for being moved outside the rotating carousel along a path that makes the forming units interact with a plurality of carousels. This path enables the time available to insert the dose inside the die means to be increased.
Furthermore, providing die means comprising movable elements enables the volume of the forming cavity defined by the die means to be increased compared with cases in which the die means comprises only the first part 52 and the movable elements are associated with the punch. For the same dose weight, this enables the risk of parts of the dose exiting from the cavity to be reduced.
In an embodiment that is not shown, the apparatus may comprise a plurality of moulds of the known type disclosed above placed next to one another in a rectilinear arrangement.
In a further embodiment that is not shown, each mould can be used to form objects, for example preforms, by injection-moulding. In this case, with each mould an injection conduit is associated to introduce fluid plastics into the mould.
In another embodiment that is not shown, the mould 1 comprises more than two movable elements, for example three or four movable elements that are drivable between a contact position and a disengagement position in similar ways to those disclosed previously.
It is furthermore also possible to provide a mould having movable elements included in the die means and further movable elements associated with the punch.
The mould can be provided with fixed die means and with a movable punch to enable the preform 4 to be formed and extracted.
With reference to FIGS. 8 to 14, there is shown a mould 101 of an apparatus for forming heads 104 for example of tubes of toothpaste, by compression-moulding of plastics. The apparatus may comprise a plurality of moulds 101, arranged peripherally on a rotating carousel 129 as previously disclosed for the apparatus for forming preforms. Each mould 101 is initially located in an opening position, shown in
Subsequently, the mould 101 closes to form the dose 135 so as to obtain a head 104 comprising a substantially frustum-conical side wall 106 and a threaded portion 108, which are shown in
The mould 101 comprises forming means provided with first forming means 102 and second forming means 103 suitable for interacting in a direction A to form the heads 104. The first forming means 102 comprises die means connected to a fork 113 (better shown in
The first forming means 102 comprises two movable elements 107 partially surrounded by the fork 113. Each movable element 107 is provided with a forming end 132 having a first forming surface 145 and a second forming surface 146. The first forming surfaces 145 are suitable for shaping the side wall 106 externally whereas the second forming surfaces 146 are suitable for shaping the threaded portion 108 of the head 104.
As shown in
Each movable element 107 furthermore comprises a connecting end 133 opposite the forming end 132 and connected to it by an intermediate portion 167 provided with a substantially rectangular transverse section, as shown in
Each connecting end 133 is rotatably connected by a hinge 111 to a support element 110 that is slidable in direction A inside a housing 127, as shown in
Onto the lower portion 147 a bush 170 is screwed, which is shown in
Inside the lower portion 147 a blind hole 151 is obtained, shown in
A first spring 140 is interposed between a first projection 141, obtained on the housing 127, and a second projection 143, obtained on the locking sleeve 139. The first spring 140 exerts a force parallel to the direction A, in such a way as to push the second projection 143 towards an arrest element 144 fixed to the carousel 129, partially projecting the protruding end 142 outside the housing 127.
As shown in
The second forming means 103 comprises a punch 134 and is driven by a piston 114 slidable in the direction A inside a cylindrical support 131 fixed to the carousel 129, as shown in
As shown in
The punch 134, the first and second forming surfaces 145 and 146 obtained on the movable elements 107, the third forming surface 150 of the bush 170 and the fourth forming surface 162 define in the closing position shown in
The punch 134 is provided with an active end 105, suitable for cooperating with the first forming means 102, comprising a pointed portion 125 suitable for interacting with the protruding portion 116, a first active surface 137 and a second active surface 122 shown in
During operation, when the mould 101 is arranged in an opening position shown in
The contact position of the movable elements 107 is reached when the column 112, moved by the driving element 121, brings the fork 113 and the support element 110 fixed relative to it near to the housing 127. The movable elements 107 assembled on the support element 110 are in turn partially introduced into the locking sleeve 139 until they interact with the protruding end 142. At this point the coupling surfaces 118 engage with the complementary coupling surfaces 119, opposing the action of the elastic retractors 149 in such a way as to place the movable elements 107 next to one another and to the lower portion 147. In this position the forming ends 132 are in contact with one another and define a forming recess 100.
When the dose 135 has been introduced into the mould 101, the piston 114 drives the second forming means 103 towards the first forming means 102, in the direction A. The further sleeve 155 approaches the movable elements 107 until the fourth forming surface 162 is brought into contact with a stop surface 163 provided on the forming ends 132 and shown in
In this position, the stop surface 163 and the fourth forming surface 162 define a closing plane of the mould 101. In this way a maximum longitudinal dimension H of the chamber 126 is thus defined in the direction A, as shown in
Subsequently, the forming ends 132 push the further sleeve 155 inside the further housing 154, which further sleeve 155 approaches the stop ring 160, compressing the further spring 120.
Furthermore, the second forming means 103 pushes upwards the first forming means 102, compressing in order the first spring 140, the second spring 190 and the third spring 191. During this movement, the protruding ends 142 of the locking sleeve 139 penetrate inside the housing 127. The closing position shown in
In this position the punch 134, pushed by the piston 114, engages in the forming recess 100, shaping the dose 135. In the meantime, the pointed portion 125 comes into contact with the protruding portion 116 and pushes the centring element 161 inside the blind hole 151 against the force of the elastic element 152. In particular, the pointed portion 125 is received inside the bush 170, going beyond the third forming surface 150.
In the closing position in
In particular, if into the mould 101 a dose 135 is introduced having a greater weight than the nominal weight, the punch 134, under the thrust of the plastics, moves away from the first forming means 102, increasing the volume of the chamber 126. In order to do so, the punch 134 recedes inside the further housing 154, opposing the Belleville-type spring 157.
If, on the other hand, a relatively small dose is introduced, the punch 134 is pushed inside the housing 154 by a reduced amount, diminishing the volume of the chamber 126.
In other words, the position of the punch 134 in relation to the first forming means 102, i.e. the distance between the first active surface 137 and the first forming surface 145, varies according to the weight of the dose 135. On the other hand, the maximum longitudinal dimension H of the chamber 126 is kept constant, being determined by the relative position of the third forming surface 150 and of the fourth forming surface 162, which remains unvaried because the further sleeve 155, the movable elements 107 and the support element 110 act in this phase as a single body.
In this way, heads 104 are obtained having a constant height and a side wall 106 thickness that is variable according to the weight of the dose 135.
The dose 135, which is shaped in such a way as to form the head 104, remains inside the chamber 126 for the time necessary for the stabilisation and the cooling of the head 104. During this phase, the first forming means 102 and the second forming means 103 are cooled by a refrigerant fluid circulating inside suitable passage conduits obtained in the mould 101.
Subsequently, by means of the piston 114 the second forming means 103 is disengaged and moved away from the first forming means 102, which continues to support the head 104 owing to the undercuts of the threaded portion 108. Whilst the second forming means 103 moves away from the first forming means 102, the pointed portion 125 exits the blind hole 151, making the centring element 161 protrude outside under the thrust of the elastic element 152 and be centred in the opening 109 of the head 104, as shown in
For this purpose, the centring element 161 is provided with a diameter that is slightly less than the diameter of the pointed portion 125. This enables the centring element 161 to enter inside the opening 109 although the diameter of the opening 109 diminishes due to the shrinkages that occur in the instants following moulding.
Subsequently, the driving element 121 and the cam guide 128 drive the fork 113 in the direction A away from the arrest element 144 in such a way as to disengage the movable elements 107 from the locking sleeve 139. The movable elements 107, pushed by the elastic retractors 149, move away from one another in such a way as to disengage the forming ends 132 from the head 104. In particular, the movable elements 107 describe an arched trajectory having a component parallel to the direction A.
As shown in
At this point the mould 101 is ready for a new forming cycle.
In an embodiment that is not shown of the apparatus disclosed above, it is possible to provide a mould in which, in the closing position, the punch is fixed and the movable elements, the further sleeve and the support element can move fixed relative to one another to perform the compensating action. Furthermore, to take the mould to the closing position, it is also possible to move the first forming means by bringing it near to the punch or simultaneously move both the punch and the first forming means.
Lastly, the direction A can be vertical, as shown in FIGS. 8 to 11, but also horizontal or tilted.
With reference to FIGS. 15 to 18, there is shown a mould 201 of an apparatus for forming heads 204 of tubes by compression-moulding of plastics, the mould 201 comprising forming means provided with first forming means 202 and second forming means 203 suitable for interacting in a direction A. The apparatus may comprise a plurality of moulds 201, arranged peripherally on a rotatable carousel 229, as disclosed previously with reference to FIGS. 1 to 4.
The mould 201 differs from the mould 101 shown in FIGS. 8 to 14 by the ways of varying the volume of the chamber in which the plastics are formed according to the weight of plastics to be formed. The differences between the two types of mould will be highlighted below, without again disclosing the parts that they have in common.
As shown in
The second forming means 203 comprises a punch 234 fixed relative to a piston 214 that enables the punch 234 to be moved in the direction A. The punch 234 comprises a first forming portion 237, suitable for internally shaping the side wall 206 of the head 204 and a second forming portion 222, suitable for internally shaping the threaded portion 208 of the head 204. From the second forming portion 222 a pointed portion 225 extends that is suitable for engaging in the indentation 265.
The punch 234 is arranged inside a sleeve 255 provided above with a further forming surface 262 suitable for forming a further end surface 264, opposite the end surface 258 of the head 204. On the sleeve 255 a containing wall 224 is obtained that is suitable for interacting with the forming ends 232, which extends upwards outside the further forming surface 262.
During operation, a dose 235 of plastics is introduced into the mould 201 arranged in an opening position, as shown in
In the closing position, the movable elements 207 engage with the sleeve 255, having their stop surface 263 in contact with the further forming surface 262. The sleeve 255, pushed by the movable elements 207, is in contact with a stop surface 266 obtained on the punch 234, overcoming the force exerted by a preloaded spring 220.
In this position, the sleeve 255, the punch 234 and the movable elements 207 act as a single body that interacts with the forming stem 261 to define a chamber 226 inside which the dose 235 is shaped. This chamber is provided with a maximum longitudinal dimension H1 parallel to the direction A, as shown in
In particular, the sleeve 255, the punch 234 and the movable elements 207 can move fixed relative to one another so that the pointed portion 225 approaches the forming stem 261 penetrating inside the indentation 265. Whilst this occurs, the distance between the further forming surface 262 and the active surface 250 of the forming stem 261 progressively decreases, i.e. the maximum longitudinal dimension H1 of the chamber 226 progressively decreases.
The degree of penetration of the pointed portion 225 inside the indentation 265 depends on the weight of the dose 235 introduced into the mould 201. In fact, if a dose having a relatively great weight has to be formed, a limited length of the pointed portion 225 engages in the indentation 265, to form a head having a maximum longitudinal dimension H1 that is the same as a first value. If, on the other hand, the dose to be formed has a relatively small weight, the pointed portion 225 penetrates more into the indentation 265. In this way a head is obtained having a maximum longitudinal dimension H1 the same as a second value that is less in relation to the first value cited above.
Nevertheless, in the closing position, the distance between the first forming surfaces 245 and the first forming portion 237 remains substantially constant, which enables heads 204 to be obtained having a side wall 206 with a constant thickness.
In other words, the punch 234, the sleeve 255 and the movable elements 207 act as forming and compensator means that define, together with the forming stem 261, a chamber 226 with a volume that is variable with the varying of the weight of the dose 235.
The head 204 remains inside the cavity 226 for the time required for stabilisation and cooling. Subsequently, the second forming means 203 disengages from the first forming means 202 whereas the movable elements 207 continue to support the head 204 engaging with the threaded portion 208, as shown in
Subsequently, the movable elements 207 are driven in such a way as to move away from one another along an arched trajectory having a component parallel to the direction A, as shown in
The mould 201 is now ready for a new forming cycle.
In an embodiment that is not shown, the volume of the cavity can be modified according to the weight of the dose by moving the forming stem in relation to the assembly comprising the sleeve, the punch and the movable elements, which are kept in a fixed position.
Furthermore, to take the mould to the closing position, it is also possible to move the first forming means by bringing it near to the punch, or simultaneously moving both the punch and the first forming means.
Lastly, the direction A may be vertical as shown in FIGS. 15 to 18, but also horizontal or tilted.
With reference to
When the cap 39 is used, the cylindrical portion 45 is introduced into the bottle 46 whereas the tamperproof ring 42 is pushed in the direction indicated by the arrow M in such a way as to break the bridge elements 44. The tamperproof ring 42 is forced to engage in a circumferal seat 47 obtained on an external surface of the side wall 43, such as to flex said wall and keep it firmly in contact with the edge portion 41 of the bottle 46, as shown in
With reference to FIGS. 21 to 26, there is shown a mould 301 of an apparatus for forming caps 39 of the type shown in
The mould 301 differs from the mould 101 shown in FIGS. 8 to 14 and from the mould 201 shown in FIGS. 15 to 18 because of certain structural elements and operating ways that will be highlighted below whereas the similarities with the previously disclosed moulds will not be disclosed in detail.
As shown in
The movable elements 307 are furthermore provided with respective connecting ends 333 opposite the forming ends 332 and hinged on the support element 310 by respective hinges 311. The movable elements 307 can be moved in a manner that is very similar to what was disclosed with reference to FIGS. 8 to 14 between a contact position in which the forming ends 332 are in contact with one another and a disengagement position in which the forming ends 332 open to enable a cap 39 to be extracted from the mould 301. Driving elements 321, shown in
The support element 310 is provided below with a shaped end 347 arranged to cooperate with the first forming surfaces 345 for internally forming the side wall 43 of the cap 39.
The support element 310 is movable in motion of translation inside a locking sleeve 339 in turn fitted in a housing 327 fixed to the carousel 329. Between the locking sleeve 339 and the housing 327 a first spring 340 is provided that keeps the locking sleeve 339 in contact below with an arrest element 344 that is connected to the carousel 329.
As shown in
Inside the support element 310 there is provided a tubular element 309 made fixed relative to the housing 327 by a threaded portion 315, as shown in
The tubular element 309 accommodates an ejector 361 having a substantially cylindrical shape and extending along the longitudinal axis Y. The ejector 361 is movable in motion of translation in relation to the tubular element 309 owing to driving means that is not shown. At a lower end of the ejector 361 a third forming surface 348 is obtained that is suitable for internally shaping a portion of the transverse wall 51 of the cap 39.
The second forming means 303 comprises a forming member 334 provided above with a fourth forming surface 349 suitable for defining the transverse wall 51 of the cap 39. The forming member 334 is provided below with an attachment flange 359 connected to a piston 314 suitable for moving the second forming means 303 in the direction A.
A sleeve 355 that is coaxial with the forming member 334 and is arranged outside it is received in a further housing 354 fixed relative to the piston 314. From an upper end zone of the sleeve 355 a containing wall 324 extends that is suitable for receiving in a shapingly coupled manner the forming ends 332 in a closing position of the mould 301. The containing wall 324 is joined to the sleeve 355 at a further stop surface 370 arranged transversely in relation to the direction A to cooperate with the stop surfaces 363 obtained on the movable elements 307.
Inside the sleeve 355 and in the proximity of the containing wall 324 a shaped portion 369 is received that is suitable for interacting with the forming member 334 and with the forming ends 332 of the movable elements 307 to form the tamperproof ring 42.
Between the sleeve 355 and the further housing 354 there is provided a further spring 320 that exerts a force that is parallel to the direction A projecting the sleeve 355 partially outside the further housing 354. In particular, the further spring 320 pushes a circumferal projection 317 obtained on the sleeve 355 against an arrest edge 336 provided inside the further housing 354.
During operation, the mould 301 is initially in an opening position shown in
Subsequently, the piston 314 drives the second forming means 303 bringing it near the first forming means 302 in the direction A, bringing the further stop surface 370 into contact with the stop surface 363, as shown in
Under the thrust of the second forming means 303, the movable elements 307 move upwards, approaching the arrest element 344 in such a way as to substantially align the stop surface 363 on the lower ends of the ejector 361 and of the tubular element 309. The mould 301 is thus in the closing position in which between the first forming means 302 and the second forming means 303 a chamber 326 is defined inside which the dose 335 is shaped to obtain the cap 39.
When the cap 39 has remained in the chamber 326 for sufficient time to stabilise its shape and the temperature has fallen to an acceptable level, the piston 314 moves the second forming means 303 away from the first forming means 302, as shown in
Subsequently, the driving means, which continues to move the ejector 361 towards the second forming means 303, elastically deforms the side wall 43 of the cap 39 disengaging it from the shaped end 347, as shown in
The moulds disclosed up to now may operate not only according to compression-moulding techniques in which a dose of plastics is separated from an extruder and introduced into the mould, but also according to injection-moulding techniques in which a fluid plastic material is injected inside a closed mould.
The features disclosed in the disclosure of the Figures with reference to a specific embodiment may also be claimed in relation to any other embodiment disclosed or may also be claimed in their own right.
| Number | Date | Country | Kind |
|---|---|---|---|
| MO2004A000144 | Jun 2004 | IT | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/IB05/01587 | 6/6/2005 | WO | 3/2/2007 |
