This application claims the benefit of priority of European Patent Application No. 13199858.5, filed Dec. 30, 2013, which is incorporated herein by reference.
The present invention relates to a unit for carrying out an operation on a container fillable with a pourable product.
Preferably, the present invention relates to a filling unit for filling the container, in particular with an aseptic pourable food product, e.g. with a delicate product which cannot be added with a substantial amount of preservative substances.
A filling unit for filling containers with an aseptic pourable food product is known from US-A-2011/0023996.
In greater detail, the filling unit substantially comprises:
In greater detail, the carousel is provided with a plurality of gripping devices for gripping the neck of respective containers and moving the containers towards and away from the respective filling device.
Still more precisely, each gripping device comprises a pair of jaws which can be moved between an open configuration in which they receive or release the neck of the container, and a closed configuration in which they firmly grip the container.
Furthermore, when the jaws are arranged in the closed configuration, the gripping device can be moved along a vertical direction between:
The filling unit also comprises a plurality of lifting devices which are operatively connected with respective gripping devices, so as to cause their movement along the vertical direction.
The known filling unit also comprises:
The gripping devices and the containers are arranged in the aseptic area.
Each lifting device has a servomotor arranged in the non-aseptic area and a rod which is driven by the servomotor and is operatively connected to the relative gripping member.
In particular, the rod has a portion, which passes through the wall. There is therefore the risk that the portion of the rod drives non-sterile air inside the aseptic area, thus contaminating the latter.
In order to contain that risk of contamination, each lifting device comprises a bellow which is interposed between a fixed part of the lifting device and an end of the rod.
The end of the rod is arranged in the aseptic area and the bellow seals the portion of the rod arranged in the aseptic-area.
Still more precisely, each bellow is arranged between the relative gripping device and the pouring opening relative filling device.
Furthermore, each bellow is arranged over the mouth of the respective container.
There is therefore the risk that, due the inevitable leakage of the bellows, the non-sterile air can reach the mouths of the containers when the respective gripping devices are in the lowered position, and contaminate either the containers or the food product contained in the containers, thus affecting the asepticity of the filling operation.
A need is felt within the industry to improve as far as possible the asepticity of the pourable product filled in the containers.
It is an object of the present invention to provide a unit for carrying out an operation on a container fillable with pourable product, which allows to easily and cost-effectively meet the above-identified requirement.
The aforementioned object is achieved by the present invention as it relates to a unit for carrying out an operation on a container fillable with a pourable product.
One preferred embodiment is hereinafter disclosed for a better understanding of the present invention, by way of non-limitative example and with reference to the accompanying drawings, in which:
With reference to
Preferably, filling unit 1 is adapted to fill containers 2 under aseptic conditions with a pourable product which does not contain preservative substances.
With reference to
In greater detail, filling unit 1 substantially comprises (
Carousel 3 also includes a tank (not-shown) common to all filling devices 10 and which is filled with the pourable food product.
Each container 2 comprises (
Unit 1 further comprises:
Wall 8 rotates integrally with carousel 3 about axis A and is passed through by filling devices 10.
Area 6 is kept at a first value of pressure whereas area 7 is kept at a second value of pressure greater than the first value.
Unit 1 also comprises a hydraulic barrier 9 for hydraulically separating non-aseptic area 6 from aseptic area 7.
In the embodiment shown, hydraulic barrier 9 is formed by a siphon, which is stationary with respect to axis A.
Siphon is filled with a bactericide substance.
Hydraulic barrier 9 prevents the flow of non-sterile air from non aseptic area 6 and aseptic area 7 at the interface between carousel 3 and frame 4.
For simplicity, the following description will refer to only one filling device 10 and to relative container 2, as devices 10 are identical to one another.
Filling device 10 substantially comprises (
Body 19 comprises, in turn, proceeding along axis B:
In the embodiment shown, shutter 16 comprises:
Plunger 25 is conical of axis B and comprises a conical end on the side of opening 21 shaped correspondingly to the shape of opening 21.
Shutter 16 is movable relative to body 19 and along axis B between:
Gripping device 17 is movable together and synchronously with filling device 10 and carousel 3 about axis A.
Furthermore, gripping device 17 is movable parallel to axis B between:
In the embodiment shown, when gripping device 17 is in the raised operative position:
Still more precisely, gripping device 17 moves from the lowered rest position to the raised operative position at station I and moves from the raised operative position to the lowered rest position at station O.
Gripping device 17 comprises, in turn:
Jaws 30, 31 can me moved between:
In particular, jaws 30, 31 move from the open configuration to the closed configuration at station I, remain in the closed configuration from station I to station O, and move from the closed configuration to the open configuration at station O.
Unit 1 also comprises:
Gripping device 17 and container 2 are arranged in aseptic area 7.
Connecting element 50 substantially comprises (
Furthermore, connecting element 50 comprises an actuator 51, which exerts an action on the rods 52 parallel to axes D and directed towards cam follower 48 against the action of cam.
In particular, the action exerted by actuator 51 is upwardly directed in the embodiment shown.
Actuator 51 is arranged in non-aseptic area 6 and bellows 53 are arranged in aseptic area 7.
Actuator 51 is, in the embodiment shown, a pneumatic actuator and behaves as a pneumatic spring which acts against the action of cam on cam follower 48.
Housings 54 are stationary with respect to relative axes D, are shaped as hollow cylinder and slidably house relative rods 52.
Furthermore, housings 54 are arranged in part in non aseptic area 6 and in part in aseptic area 7.
Each rod 52 comprises:
End 55 is fitted to a shaft 49, which extends along an axis E and rotates about axis E integrally with cam follower 48.
Axis E is, in the embodiment shown, orthogonal to axes A, B, C, D and horizontal.
Under the action of cam, rods 52 are movable between:
Plate 60 and columns 61 connect rods 52 with gripping device 17.
Accordingly, when rods 52 are arranged in the uppermost position, gripping device 17 is in the operative raised position and bellows 53 assume their minimum length (
When rods 52 are arranged in the lowermost position, gripping device 17 is in the rest lowered position and bellows 53 assume their maximum length.
Advantageously, bellows 53 are arranged on the opposite side of gripping device 17 with respect to opening 21 of filling device 10 (
In this way, bellows 53 prevent portions 57 of rods 52 from conveying non-sterile air from non sterile area 6 to sterile area 7.
Bellows 53 are arranged below gripping device 17 and below mouth 11 of container 2.
In particular, connecting element 50 comprises:
In detail, columns 61 extend parallel to axes C.
Each bellow 53 comprises:
End 66 is furthermore sandwiched between end 56 of respective rod 52 and plate 60, as shown in
End 65 is, in the embodiment shown, arranged above end 66.
Unit 1 also comprises:
Ventilating means 70 are adapted to maintain the pressure in aseptic area 7 at a higher value than in non-aseptic area 6.
In greater detail, ventilating means 70 create an airflow, which is directed from gripping device 17 towards bellows 53.
That airflow tend to a laminar condition, in the embodiment shown.
In this way, the air that escapes from bellows 53 is directed on the opposite side of mouth 11 of container 2.
Ventilating means 70 comprise, in the embodiment shown, a plurality of fans.
The capping unit is housed inside aseptic area 7.
The operation of filling unit 1 and machine 5 will be now described with reference to only one container 2, only one gripping device 17 and only one connecting element 50.
In particular, container 2 is inside aseptic area 7, when it is conveyed inside unit 1, filled with pourable food product, conveyed to capping unit and capped.
Furthermore, bellows 53 and gripping device 17 are arranged in aseptic area 7.
On the contrary, cam follower 48 and actuator 51 are arranged in non aseptic area 6.
Ends 55 of rods 52 are arranged in non aseptic area 6, portions 57 of ends 55 moves between non aseptic area 6 and aseptic area 7, ends 56 of rods 52 are arranged in aseptic area 7.
Housings 54 are arranged in part inside non aseptic area 6 and in part inside aseptic area 7.
Ventilating means 70 creates an airflow current from non-aseptic area 6 towards aseptic area 7.
That airflow is filtered by filtering means upstream from aseptic area 7, so that the non-sterile component cannot reach aseptic area 7
Hydraulic barrier 9 prevents the flow of non sterilized substances from non aseptic area 6 towards aseptic area 7, at the interface between frame 4 and carousel 3.
Furthermore, the operation of filling unit 1 will be now described starting from a configuration in which connecting element 50 is arranged at station I of path P and in which shutter 16 is in the closed configuration.
At station I, the interaction between cam and cam follower 48 keeps rods 52 in the lowermost position and therefore gripping device 17 in the lowered rest position.
As carousel 3 advances along path P, rods 52 upwards slide inside housings 54 parallel to axis D. This is due both to the shape of cam which contacts cam follower 48 and to the upwards action exerted by actuator 51 on rods 52.
The upwards sliding of rods 52 causes an upward movement of plate 60, columns 61 and gripping device 17.
As a result, rods 52 reach the uppermost position and the length of bellows 53 parallel to axes D decreases up to the minimum value (
As gripping device 17 reaches the operative raised position, shutter 16 is displaced in the open configuration and the pourable product can pass through opening 21 and fill container 2.
In particular, when gripping device 17 is in the operative raised position, mouth 11 is arranged at a certain distance along axis B from opening 21, in case of contactless filling with a still pourable product.
In case of contactless filling with a carbonated pourable product, mouth 11 is in tight-fluid contact with opening 21 when gripping device 17 is in the operative raised position.
When a given amount of pourable product has filled container 2, shutter 16 moves back in the closed position.
When connecting element 50 reaches station O, the interaction of cam with cam follower 48 downwards moves rods 52 along axes D, thus causing the movement of gripping device 17 in the lowered rest position.
The downwards sliding of rods 52 with respect to housing 54 causes a downwards movement of plate 60, columns 61 and gripping device 17.
As a result, rods 52 reach the lowermost position along axes D and the length of bellows 53 parallel to axes D increases up to the maximum value.
In this condition, filled container 2 is withdrawn from jaws 30, 31 by a not-shown conveyor, e.g. a star wheel and conveyed, in a not-shown way, to the capping unit.
During the movement of rods 52 along respective axes D, respective portions 57 move between non aseptic area 6 and aseptic area 7.
Bellows 53 prevents the non sterile air driven by portions 57 from escaping inside aseptic area 7.
In case of leakage of bellows 53, the leaked non sterile air is driven by airflow generated by ventilating means 70 on the opposite side of gripping device 17.
In this way, the risk of contaminating container 2 and/or the pourable product filled therein is dramatically reduced.
From an analysis of the features of unit 1 according to the present invention, the advantages it allows to obtain are apparent.
In particular, bellows 53 are arranged on the opposite side of gripping device 17 with respect to openings 21 of filling devices 10.
In this way, the non sterile air that leaks from bellows 53 is substantially prevented to reach mouth 11 of containers 2, when the latter are spaced from respective openings 21 along respective axes B.
Accordingly, the risk of contamination of containers 2 and/or the pourable product is dramatically reduced when compared with the known solutions discussed in the introductory part of the present description.
The level of asepticity of the pourable food product is correspondingly enhanced in comparison with the above-identified known solutions.
Furthermore, the airflow generated by ventilating means 70 contributes to direct the non sterile area leaked from bellows 53 on the opposite side of gripping device 17 and, therefore, of containers 2 along axes D.
Finally, it is apparent that modifications and variants not departing from the scope of protection of the claims may be made to unit 1 disclosed herein.
In particular, unit 1 could be adapted to apply a cap onto containers 2 filled with an aseptic product.
Unit 1 could also be adapted to carry out an operation onto containers 2 under non aseptic condition, especially to fill containers 2 with non aseptic products.
Furthermore, ventilators 70 can create respective non-laminar, i.e. turbulent, airflows.
Finally, in case of contact filling with pourable product containing carbonated substances, the vacuum could be created inside containers 2 and/or a pressurization step could be carried out onto containers 2 before the filling thereof and/or a depressurization step could be carried out onto containers 2 after the filling step thereof.
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European Search Report in EP 13199858, dated May 12, 2014 (6 pages). |
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20150183538 A1 | Jul 2015 | US |