Title of Invention

FORMING CONTAINERS

Abstract Abstract A method comprises forming a preform (51) of plastic matter, expanding said preform (51) to obtain a container (4), said forming comprising compression-forming said preform (51) in that mould means (2) in which said expanding occurs; a method comprises expanding a preform (51) in mould means (2) to obtain a container (4), before said expanding it being provided to form a dose of plastic material (55) in a paste state in said mould means (2) to obtain said preform (51); an apparatus comprises forming mould means (2), punch means (40) for expanding a preform (51) in said mould means (2), abutting means (30) cooperating with said punch means (40), said punch means (40) and said abutting means (30) identifying a configuration in which said punch means (40) and said abutting means (30) cooperate to define a forming unit for compressionforming a semifinished product of plastic material (50; 53; 55) to obtain said preform (51) and a further configuration in which said punch means (40) and said abutting means (30) cooperate to define an expansion unit of said preform to obtain a container.
Full Text

Forming containers
The invention relates to forming containers from a semifinished product, for example in plastic material such as a pad formed by injection, or a disc or a dose of plastic material in a paste state.
The state of the art comprises systems for thermoforming containers from flat film in single-layered or multilayered plastic matter.
US 2854694 discloses a method for forming hollow articles or containers from materials in plastic condition, such as hot thermoplastic material or other material in sheet form. The material in sheet form and in a plastic condition is positioned over a female mold which may be of hollow cylindrical form and is gripped between the mold and a hold down element. The material is then pressed between a plunger and a bottom plate and also pressed at the same time between the body mold and the hold down member in a manner to thicken and increase the volume of the plastic material surrounding the plunger, thus accumulating sufficient material for forming side walls of adequate thickness. This accumulated material is stretched downward to form side walls by downward movement of the male die or plunger and the bottom plunger relative to the hollow mold.
US 4159977 discloses a tubular plastic container having a molecularly oriented sidewall portion which is made by bringing the peripheral portion of a solid blank in engagement with the shoulder portion of a die, introducing the blank into a cavity of the die while compressing with a first and second plungers, such that in the former stage of the introduction, the speed is relatively low and the pressure is relatively high, and then the speed is increased at a controlled rate and the pressure is decreased, thereby forming a hollow molded piece, and then expanding the molded piece to bringing the

sidewall portion thereof into contact with the inner surface of the cavity.
DE 1479583 discloses a method in which a hollow article is formed from a heated blank, of synthetic plastics material, by clamping the blank about the mouth of a split mould, drawing the blank using co-operating heated plungers and finally expanding the drawn blank into conformity with the mould. During the co-ordinated drawing movement of the plungers, the upper plunger is moved relatively towards the lower plunger to express material from therebetween, which material forms the lower regions of the wall of the finished container and has a high degree of molecular orientation imparted thereto. The final separation of the two plungers determines the ultimate wall and bottom thickness of the finished article.

> The invention go la tee to forming oontoinero from^u*
semifinished product, for example in plastic matetiarir^such as a pad formed by injection, or a disc^j^r^Tdose of plastic
material in a paste state
The state of thg^-al^comprises systems for thermoforming contaijifrpe—from flat film in single-layered or multilayered rr-pXactic aatteri 1 Systems are furthermore known for forming containers that provide for expanding, by means of pressurised air, in a forming mould, a preform of a container obtained by injection. JP - 2001 000362600, publication JP - 2003 159743, is furthermore known that discloses a system for forming containers comprising in sequence:
positioning a semifinished disc-shaped product in plastic material near an opening of a forming mould for forming containers;
expanding said semifinished product in said forming mould by means of a punch inserted into said mould through said opening.' Before being positioned near the opening, the semifinished product is formed in a suitable forming mould for forming the semifinished product, in which a dose of thermoformable plastic material is placed between a punch and a die that can be moved up to and be removed from one another to give the dose the desired shape*
JP -'2001 000362600 therefore has the drawback of using - two types of mould, i.e. a mould for forming the semifinished product and a mould for forming containers.
Furthermore, JP - 2001 000362600 involves subjecting the plastic material to a complete heating and cooling cycle to form the semifinished product and to a further heating and cooling cycle to form the container.

US 6,264,050 discloses a forming system in which, starting
from a sheet material, precursors of containers are formed
that are then separated from the sheet material and expanded
in a forming mould by compressed air to obtain formed
containers.
US 6,264f050 has the drawback of using different apparatuses
to form the precursors and to expand the latter to obtain
containers.
An object of the invention is to improve the known systems to
obtain containers.
A further object is to make the manufacturing systems for
blown containers more compact.
A further object is to improve the forming conditions of a
semifinished element positioned near the opening of a forming
mould for forming containers.
In a first aspect of the invention, there is provided a method
oomprioingi A£6oAlVirvJG TO CtAm A .
in forming a perform of platio matter expanding said preform to obtain a container; wherein said forming comprises compression-fjpanfng said preform in that mould means in which said expatfifing occurs.
In a second aspect of the inventipn-^there is provided a
method comprising:
expanding a pre£p«f* into mould means to obtain a
container ,^-*^*^ wherein b£f puncb^-aeens for expanding a preform in said forming
-*— mould moans; 1

abuting Rteaac cooperating with said punoh mong
wherein said punch means and said abutting means identify a configuration in which said punch means ajaeb-^said abutting means cooperate to define a comgpfrffSion-forming unit for compression-forming a senii^ifiished product in plastic material to obtains^id^preform, and a further configuration in which sa^d^ptinch means and said abutting means cooperate to «^oontaino3Fi—\ Owing to these aspects of the invention, it is possible, to form containers from semifinished products located in a single forming mould* In fact, the semifinished product to be formed i s placed at the opening of the mould means, i s then shaped to obtain a preform and this preform is then expanded without the preform having to be extracted from the mould means, as on the other hand occurs in known forming systems.
Furthermore, it is possible to obtain better control of forming through the effect of the shaping of said semifinished product and the presence of abutting means that acts on the semifinished product together with the punch means on an opposite side of the latter. Furthermore, a particularly compact forming system it is
. obtained. Furthermore, the plastic material is subjected to a single heating cycle that comprises a progressive heating and cooling in several phases.
In particular, the invention enables containers to be obtained starting from a semifinished product in plastic material that may comprise an element with a thin thickness, for example a disc obtained by shearing from a film, or an injected body, or a dose of plastic material in a paste state.

In all the aforementioned cases, obtaining a preform by
compression-forming from the semifinished product, enables
the subsequent obtaining the container by blow-forming to be
improved.
The preliminary step of obtaining a preform having a
prefixed geometry, for example walls having different
thickness in various points of the preforms, enables in fact
a different heating phase of the preform prior to the
expansion phase of the latter to be avoided.
The advantage of being able to create a preform and
subsequently expand it appears particularly clear in the
case of the element with a thin thickness and of the dose of
plastic material in a paste state, that both could not be
subjected to an expansion phase without previously be
conformed as a preform.
In the case of the injected body, it is a question of an
element that is structurally more similar to a preform.
Nevertheless, also in this case the compression-forming of a
preform from the injected body brings significant
advantages.
Obtaining a preform in two phases (i.e. injection- and
subsequent compression-moulding) in fact enables plastic
material to be used having a high molecular weight, which is
very appreciated in order to facilitate operations of
stretch-blow-forming.
Any defects in the injected body due, for example, to the
low viscosity that is typical of plastic material with high
molecular weight, can be subsequently eliminated in the
compression-moulding phase, enabling containers that are
free of defects to be obtained.
In particular, it is possible to use injection moulds
provided with an injection opening (gate) of considerable
dimensions, in order to facilitate the flow of the plastic
matter.

The discontinuity created in the injected body by the orientation of the injection opening is subsequently eliminated during the subsequent phase of compression-forming.
The possibility of using plastic material with a high molecular weight and of obtaining preforms substantially free of defects and having walls with a controlled thickness, enables the preforms to be subjected to blowing that acts both axially and radially, in the same mould. The invention may be better understood and implemented with reference to the enclosed drawings that show some embodiments by way of non-limitative example, in which: Figure 1 is a longitudinal section of a forming apparatus, in an initial phase in which a semifinished product is supplied to a mould;
Figure 2 is a section like the one in Figure 1, showing a compression-forming phase of the semifinished product to obtain a preform;
Figure 3 is a section like the one in Figure 1, showing a phase of stretch-forming of a precursor of a container; Figure 4 is a section like the one in Figures 1 to 3, showing a blowing phase to form the container; Figure 5 is a section like the one in Figures 1 to 4, showing an extraction phase of a formed container; Figure 6 is an axial section of a container;
Figure 7 is a diagram that, shows a heating cycle to which. the plastic material can be subjected in a forming cycle of the apparatus in Figures 1 to 5;
Figure 8 is a diagram like the one in Figure 7, but relating to the state of the art;
Figure 9 is a section like the one in Figure 1, showing an embodiment in which the mould is supplied with a semifinished product obtained by injection-forming;

Figure 10 is a section like the one in Figure 1, showing an
embodiment in which the mould is supplied with a dose of
plastic material in a paste state;
Figure 11 is a section like the one in Figure 10, showing an
embodiment in which the dose of plastic material is inserted
into a mould comprised in a rotating machine;
Figure 12 is a section like the one in Figure 1, showing a
mould configuration suitable for obtaining a first container
format;
Figure 13 is a section like the one in Figure 12, showing a
further mould configuration suitable for obtaining .a second
container format;
Figure 14 is a longitudinal, fragmentary and enlarged
section of a base part of the mould in Figure 1, showing a
version of the base part;
Figure 15 is a section like the one in Figure 14, showing a
punch body subdivided into coaxial parts;
Figure 16 is a section like the one in Figure 15, showing
the body of the punch in an operating configuration that is
different from the one shown in Figure 15;
Figure 17 is a diagram that shows a further heating cycle to
which the plastic material can be subjected in a forming
cycle of the apparatus.
With reference to Figure 1, a mould 2 is shown for forming a
container 4 (see Figure 6), comprising a base plate 6 on
which there is fixed an external casing 10 of a die 8 that
is internally provided with a cavity- Within the casing 10
there is fixed a liner 12 that defines an intermediate part
14 of the cavity 9 and carries at its opposite ends a first
member 16 and a second member 18, which respectively define
a first end zone 20 and a second end zone 22 of the cavity
9.

The first member 16 has an opening 24 and defines a seat 26 in which can be received a semifinished product 50 from which the container 4 is formed.
The second member 18 receives within itself a base part 30 in an axially sliding manner as will be explained in greater detail below.
The base plate 6 has a pair of bushes 32 in which respective guide rods 34 are slidingly fitted, the respective ends of which are connected by a first crosspiece 36 and by a second crosspiece 38.
The second crosspiece 38 and the first crosspiece 36 are on opposite sides of the die 8, the second crosspiece 38 supporting a punch 4 0 turned towards the die 8. The punch 4 0 and the base part 30 are movable inside the die 8 independently of one another, in such a way as to identify a first configuration, in which the punch 40 and the base part 30 cooperate to define a forming unit for compression-forming the semifinished product 50 to obtain a preform 51, and a second configuration, in which the punch 40 and the base part 30 cooperate to define an expansion unit for the expansion of the preform 51 to obtain the container 4. In particular, in the first configuration, the punch 40 and the base part 30 are arranged near the opening 24. In the first configuration the base part 30 cooperates with the die 8 to define a chamber inside which the punch 4 0 can penetrate to press the plastic material against wall means delimiting said chamber.
Subsequently, after the preform 51 has been formed, the base part 30 and the punch 40 are removed from the opening 24 to identify the second configuration, in which the base part 30 cooperates with the die 8 to define a further chamber inside which the punch 40 expands the preform 51 to obtain the container 4.

The punch 40 comprises a punch body 42 inside which is
axially slideable a stem 44 passing through a hole 45 of the
second crosspiece 38 and having a shaped head 46 turned
towards the die 8.
The head 4 6 is housed in a chamber 4 8 provided in the punch
body 42 into which an operating fluid, for example air at
controlled pressure, can be introduced and from which it can
be extracted.
In the position in Figure 1, a disc shaped semifinished
product 50 is positioned in the seat 26 at the opening 24.
The semifinished product 50 is obtained by shearing from a
single-layer or multilayered film.
The first crosspiece 36 is kept fixed and the base plate 6
is made to slide on the pair of rods 34 in the direction
indicated by the arrow F to bring the first crosspiece 36 up
to the punch 40, as shown in Figure 2.
In this way, the top surface 52 of the die 8 approaches an
annular front surface 56 of the punch 40 in such a way that
an axial and central projection 54 of the latter penetrates
inside the seat 2 6 and interacts with the surface of the
semifinished product 50 turned towards it.
Once the projection 54 is in. the interaction position
disclosed above, the base part 30 is taken by an actuator 60
in the direction indicated by the arrow Fl through the
cavity 9 to the opening 24 in such a way as to interact with
a further surface of the semifinished product 50 opposite
the surface that is in contact with the shaped head 46.
In this interaction position, temperature control means (not
shown) intervenes on the semifinished product 50 in such a
way as to take it to the thermoforming temperature whereas
the semifinished product 50 is shaped by the combined action
of the shaped head 46 and the base part 30.

Alternatively, the semifinished product 50 can be positioned
in seat 26 when it is already at the temperature at which
compression-forming occurs.
Subsequently, now with reference to Figure 3, whilst the
base plate 6 is kept in the position disclosed in Figure 2,
the base part 30 is returned by the actuator 60 to its
initial position in a direction F2 opposite direction Fl.
Furthermore, the stem 4 4 shifts the shaped head 4 6 to the
base part 30, stopping before reaching it. In this way, the
semifinished product 50 has a peripheral part tightened
between the projection 54 and the seat 26 and a central part
that is drawn by the shaped head 4 6 to form a precursor 58
of a container.
With reference to Figure 4, compressed air is introduced
into the chamber 4 8 that occupies the precursor 58 of a
container and expands the precursor 58 until it reaches the
walls that define the cavity 9.
This is made possible by the fact that the stem 44 has a
transverse dimension that is smaller than that of the shaped
head 4 6 and therefore when the shaped head 4 6 is outside the
chamber 4 8, the air that is introduced into the chamber 4 8
can exit by the side of the head 46.
With reference to Figure 5, it is shown how, in order to
extract the shaped container 4, it is necessary to open the
die 8 by separating the casing and liner parts and the
inserts that make it up.
As shown in Figure 6, the container 4 has a flange 62
radially protruding from a neck 64 that leads away from a
converging wall part 66 that is joined to a central wall
part 68.
A base 70 has a peripheral support edge 12 that converge
into a divergent wall 74 connected to the central wall part
68.

In Figure 7 the temperature levels are shown in a forming cycle of the container 4 in the apparatus 1 of Figures 1 to 5.
During a first phase, the semifinished product 50 is heated to temperature Ti, advantageously coinciding with the plasticization temperature of the plastic matter, i.e. the temperature at which compression-forming of the preform occurs. After a set period of time in which the semifinished product 50 is maintained at the temperature Ti, the semifinished product is cooled to the temperature T2, advantageously coinciding with the forming temperature, i.e. the temperature at which stretch-blow-forming of the container occurs.
At temperature T2 the preform is expanded to create a container. The container is kept at temperature T2 for a certain period of time and is then progressively cooled to temperature T3/ coinciding for example with ambient temperature.
In the diagram in Figure 8, in which the typical temperature levels of a system for forming containers according to the state of the art are shown, for example JP - 2001 000362600, it is noted how after bringing the material to temperature Ti i.e. to plasticization temperature, to obtain a preform in a first mould for forming preforms, the preform has to be cooled to temperature T3, for example to ambient temperature, and be subsequently heated in a second mould for forming the containers.
As shown with reference to Figure 9, in the seat 26 there is inserted, instead of the disc 50, a semifinished product 53 injection-formed before it is inserted into the seat 26 in a suitable mould that is not shown. The semifinished product 53 has a substantially circular shape with a central depression, but more in general, it may have any suitable shape, according to necessity, to obtain a preform 51 shown

in Figure 2, and it acts as a preliminary preform to obtain
the preform 51.
Figure 10 shows a variation in which instead of a disc 50,
or of a preliminary preform 53, the semifinished product to
be positioned near the opening 24 comprises a dose 55 of
extruded plastic material in a paste state. In this
embodiment, unlike what has been described with reference to
Figures 1 to 9, the base part 30 is in a position near the
opening 24 in such a way as to substantially occupy it,
preventing the dose from falling into the cavity 9 in an
uncontrolled manner. The dose 55 is thus released on the
base part 30, when the latter is in the position shown in
Figure 10 waiting to cooperate with the punch 40 to give
rise to the preform 51.
In this embodiment, the dose of plastic matter, when it is
positioned on the base part 30, is already at the
temperature at which compression-forming of the preform 51
occurs.
For this purpose, the dose of plastic material can be
extruded and subsequently cooled inside the extruder to the
temperature at which compression-forming occurs.
Alternatively, two serially arranged extruders can be
provided.
The apparatus embodiments in Figures 9 and 10 operate, in
terms of forming of the preform 51, and the subsequent
forming of the container 4, as already disclosed with
reference to Figures 2 to 5.
With reference to Figure 17, the -temperature levels in a
forming cycle of the container 4 are shown, the latters
being different from the ones of the forming 'cycle in Figure
7.
Initially, a semifinished product, such as a flat element,
or an injected body, or a dose of plastic material in a
paste state, is introduced into the mould 2, this

semifinished product having been previously heated to a
temperature Ti, at which temperature the semifinished
product is compression-formed to create a preform 51.
Subsequently, the semifinished product is kept at a
temperature TV , at least during the compression- forming
phase.
Thereafter, the perform 51 thereby obtained is expanded to
create a container 4.
Expansion of the preform occurs at a temperature T2' that is
lower than the temperature Ti', the difference between the
temperature TV and T2' being rather limited. In other
words, the temperature Ti' and T2' are near to each other.
In a further heating cycle, which is not shown, the
temperature at which expansion of the preform occurs
substantially coincides with the temperature at which the
preform was compression-formed.
A small or possibly non-existent difference between the
temperature at which expansion of the preform occurs and the
temperature at which the preform was compression-formed
enables a more uniform distribution of the temperature to be
obtained in the thickness ' of the preform, and therefore
enables stretch-blow-forming to be optimised.
The container obtained is subsequently cooled to a
temperature T3' .
As shown in Figure 11, a forming apparatus similar to the
one disclosed with reference to Figures 1 to 10 can also be
fitted onto a rotating machine.
In the particular case in which forming of the container
occurs starting from a dose 55 of plastic material in a
paste state, it is provided for that the dose is conveyed
above the opening 24 occupied by the base part 30 by a
turntable 100 that is made to rotate around an axis B
parallel to the longitudinal axis A. In a peripheral zone of
the turntable 100 spoons 101 are supported by a side of the

table, which spoons 101 pick up a dose 55 from an outlet 102 of an extruder 103 and deposit it on the base part 30 in a raised position.
The base part 30 is a component of the cavity 8 fitted to a bottom part 104 of a carousel 105 that is rotatable around a main axis C of the machine. The bottom part 104 can thus be provided with a plurality of cavities distributed along its periphery. The carousel 105 is provided with a top part 10 6 fitted with a corresponding plurality of punches superimposed on the cavities 8.
On the turntable 100 a star 107 is fitted that is provided with arms 108 between which gaps 109 are defined between which the formed containers 4 are received singly that are released by the respective punches 40.
The containers 4 are picked up by the punches 40 by means of the star 107 and are transferred by the arms 108 to an unloading zone S whilst they rest on the turntable 100. In one version, that is not shown, a plurality of apparatuses 1 can be provided that are fitted to form a set of pressing units arranged in line.
From the comparison between Figures 12 and 13, it is possible to provide that the base part 30 can be positioned at variable distances from the top of the cavity 8. In this way, it is possible to use the same cavity 8 to obtain different formats of containers 4, 4' by simply arranging the base part 30 at different distances from the top of the cavity 8. In particular, it is shown how the different arrangement of the base part can provide containers that differ from one another by a preset height H. In such cases, it is preferable for the intermediate part 14 to have a cylindrical form with constant cross-section that extends at least for a portion that occupies the possible different positions that the base part 30 can take up.

The head 4 6 and/or the base part 30 may be made of several parts arranged concentrically in relation to one another, in such a way as to make possible to form preforms 51, or containers 4, having the most widely varying geometries. For this purpose, the parts that form the head 4 6 and/or the base part 30 are slideable in relation to one another and can be independently powered.
With reference to Figure 14, it is shown how the base part 30 may comprise a central portion 80 surrounded by a peripheral portion 82 that may slide axially along a longitudinal axis A of the mould 2 in relation to the central portion 80. In this way, the central portion 80 can for example be positioned either in such a way that its internal surface 84 is substantially coplanar with an internal peripheral surface 86 of the peripheral portion 82 to form a substantially flat container base.
Alternatively, as shown by the broken line, the internal surface 84 can be shifted further to the inside of the cavity 9 in such a way as to form a container base that has a central zone 70a that is raised in relation to the peripheral edge 72.
With reference to Figure 15, it is shown how the shaped head 46 comprises an external annular part 200 and an internal annular part 202, both of which are driven independently in a direction W parallel to the axis A. In this way it is possible to move the internal part 202 and the external part 200, as well as the central portion 80 and the peripheral portion 82, in such a way as to enable a preform 51 to be obtained as shown in Figure 2. In particular, the central portion 80 faces the internal part 202 and substantially has a transverse dimension that is larger than that of the latter. In this way it is possible, as shown in Figure 16, for the internal part 202 to penetrate inside the peripheral

portion 82 in such a way as to give rise to a central projection 206 in a preform 204.







CLAIMS
1. Method comprising:
expanding a preform (51) in mould means (2) to
obtain a container (4), characterized in that before said expanding, compression-forming an extruded dose of plastic material (55) in a paste state in said mould means (2) to obtain said preform (51) is provided.
2. Method according to claim 1, wherein said forming occurs near an opening (24) of said mould means (2).
3• Method according to claim 2, wherein said forming
comprises tightening said dose (55) between punch means
(40) and abutting means (30) that is part of die means
(8) of said mould means (2), said punch means (40) and
sai d abutt ing means (30) being arranged near said
opening (24).
4. Method according to claim 3, wherein before said forming, arranging said abutting means (3 0) near said opening (24) to receive said dose (55) is provided.
5. Method according to claim 3, or 4, wherein after said forming, removing said abutting means (30) from said opening is provided.
6. Method according to claim 5, wherein said removing comprises shifting said abutting means (30) until it is defined part of a cavity (9) of said die means (8) situated on the opposite side of said cavity (9) in relation to said opening (24) .
7. Method according to any one of claims 3 to 6, wherein said expanding comprises introducing a shaped head (46) of said punch means (40) through said opening (24) towards said abutting means (30) .
8. Method according to any one of claims 3 to 7, wherein said expanding comprises introducing a forming fluid through said punch means (40).

9. Method according to any one of claims 3 to 8, wherein said abutting means (30) is shaped in such a way as to cooperate to form a base (70) of a container (4).
10. Method according to any one of claims 3 to 9, wherein said abutting means (30) is positioned at different distances from the top of said die means (8) to form containers (4; 4') having formats that are correspondingly different from one another.
11. Apparatus comprising:
forming mould means (2) ,
punch means (40) for expanding a pre form (51) in
said mould means (2),
abutting means (3 0) cooperating with said punch
means (40), wherein said punch means (40) and said abutting means (30) define a configuration in which said punch means (40) and said abutting means (30) cooperate to define a compress ion-forming unit in which said preform (51) is obtained from an extruded dose (55) of plastic material in a paste state, said compression-forming unit being provided with a cavity having the same shape of said preform (51), and a further configuration in which said punch means (40) and said abutting means (30) cooperate to define a blow-moulding unit in which said preform is expanded to obtain a container.
12. Apparatus according to claim 11, 'wherein, in said configuration, said abutting means (30) cooperates with die means (8) of said mould means (2) to define said cavity inside which said punch means (40) can penetrate to press said plastic material against wall means internally delimiting said cavity.
13. Apparatus according to claim 12, wherein, in said further configuration, said abutting means (30) cooperates with said die means (8) to define a further

cavity inside which said punch means (40) can penetrate to expand said preform (51) .
14. Apparatus according to claim 12, or 13, wherein said die means (8) comprises an opening (24), said punch means (40) and said abutting means (30) defining said compression-forming unit at said opening (24).
15. Apparatus according to claim 14, wherein said abutting means (3 0) defines a part of said cavity, or of said further cavity, located on the side opposite said cavity, or of said further cavity, in relation to said opening (24).
16. Apparatus according to claim 14, or 15, wherein said punch means (40) comprises a shaped head (46) having a transverse dimension less than said opening (24).
17- Apparatus according to any one of claims 14 to 16, wherein said abutting means (30) is shaped in such a way as to receive said dose (55) on it near said opening (24) .
18. Apparatus according to any one of claims 11 to 17 f wherein said abutting means (30) is shaped in such a way as to cooperate to form a base (70) of a container (4) .
19. Apparatus according to any one of claims 11 to 17, wherein said abutting means (30) is subdivided into portions (80, 82) made to slide in a preset direction
(A) .
20. Apparatus according to claim 19, wherein said preset direction (A) passes through a longitudinal axis of said mould means (2).
21. Apparatus according to claim 19, or 20, wherein said portions comprise a peripheral, portion (82) coaxially arranged around a central portion (80).
22. Apparatus according to claim 16, or according to any one of claims 17 to 21 as appended to claim 16, wherein said

shaped head (46) is subdivided into parts (200, 202) made to slide in a further preset direction (A).
23. Apparatus according to claim 22, wherein said further preset direction (A) passes through a longitudinal axis
24. of said mould means (2).
24. Apparatus according to claim 22, or 23, wherein said parts comprise an external part (200) coaxially arranged around an internal part (202)•
25. Apparatus according to claim 24, as claim 22 is appended to claim 21, wherein said internal part (2 02) and said peripheral portion (82) are shaped in such a way that said internal part (202) is receivable in said peripheral portion (82).
26. Apparatus according to any one of claims 11 to 25, wherein said punch means (40) comprises passage means (48) of a forming fluid.
27. A rotating forming machine comprising at least an apparatus according to any one of claims 11 to 26.


Documents:

3348-CHENP-2006 CORRESPONDENCE OTHERS 26-09-2011.pdf

3348-CHENP-2006 AMENDED CLAIMS 26-06-2012.pdf

3348-CHENP-2006 AMENDED PAGES OF SPECIFICATION 26-06-2012.pdf

3348-CHENP-2006 CORRESPONDENCE OTHERS 02-07-2012.pdf

3348-CHENP-2006 EXAMINATION REPORT REPLY RECEIVED. 26-06-2012.pdf

3348-CHENP-2006 FORM-3 26-06-2012.pdf

3348-CHENP-2006 OTHER PATENT DOCUMENT 26-06-2012.pdf

3348-CHENP-2006 POWER OF ATTORNEY 02-07-2012.pdf

3348-CHENP-2006 POWER OF ATTORNEY 26-06-2012.pdf

3348-chenp-2006-abstract.pdf

3348-chenp-2006-claims.pdf

3348-chenp-2006-correspondnece-others.pdf

3348-chenp-2006-description(complete).pdf

3348-chenp-2006-drawings.pdf

3348-chenp-2006-form 1.pdf

3348-chenp-2006-form 3.pdf

3348-chenp-2006-form 5.pdf

3348-chenp-2006-pct.pdf


Patent Number 253982
Indian Patent Application Number 3348/CHENP/2006
PG Journal Number 37/2012
Publication Date 14-Sep-2012
Grant Date 11-Sep-2012
Date of Filing 15-Sep-2006
Name of Patentee SACMI COOPERATIVA MECCANICI IMOLA SOCIETA' COOPERATIVA
Applicant Address VIA SELICE PROVINCIALE, 17/A 40026 IMOLA(BO)
Inventors:
# Inventor's Name Inventor's Address
1 MINGANTI, GIANNI VIA SELICE 94, I-40026 IMOLA(BO)
PCT International Classification Number B29C 51/42
PCT International Application Number PCT/EP05/01204
PCT International Filing date 2005-02-07
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 MO2004A000034 2004-02-16 Italy