This application is the National Phase of International Application PCT/IB2018/058826 filed Nov. 9, 2018 which designated the U.S.
This application claims priority to Italian Patent Application No. 102017000130075 filed Nov. 14, 2017, which application is incorporated by reference herein.
This invention relates to a machine for packaging soft products, such as, for example, but without limiting the scope of the invention, those for sanitary use, in particular rolls of tissue paper products such as rolls of paper for sanitary and/or household use or unwoven products such as nappies.
Currently, in the automatic machines which perform the packaging of the above-mentioned products, the products are grouped together in one or more layers, such as, for example, layers composed of several rolls aligned in rows, and they are sent to a feed station downstream of which there is a packaging unit.
For reasons of simplicity, a machine for making packaging rolls is described below.
The purpose of the packaging unit is to wrap the group of rolls with a sheet of heat-sealable wrapping material, for example, but without restricting the scope of the invention, made of transparent polypropylene, and to stabilise the wrapper thus obtained.
According to a known machine configuration, the station for feeding the rolls and the packaging unit are arranged one after another, the first beneath the second and with the interposition of a horizontal elevator plate which receives the rolls in a predetermined format from the feed station and transfers them to the packaging unit.
The elevator plate lift is generally combined with two vertical walls which laterally delimit the size, that is to say, the format, of the group of rolls, and which allow the format to be stably maintained, in particular when this has two or more layers superposed on each other.
The packaging unit comprises, usually, a chain or belt conveyor, which is looped and is provided with U-shaped pockets (defined by pairs of drive teeth), designed to house respective groups of rolls. The conveyor is motor-driven in a stepwise fashion and is positioned above the feed station for stopping, at each pause, a relative pocket with the respective inlet opening facing the elevator plate.
The packaging unit is associated with a line for feeding wrapping sheets, which, simultaneously with each positioning of a pocket, feeds a sheet of wrapping material to the pocket which is positioned facing the elevator plate. The sheet of wrapping material is fed in such a way as to close the inlet opening of the pocket, so that, with the subsequent lifting of the elevator plate, the sheet is intercepted by the group of rolls and is forced by them to enter into the pocket.
The insertion of the groups of rolls in the pocket determines a U-shaped folding of the sheet of wrapping material around the group, after which the sheet of wrapping material comes out of the pocket with two relative end flaps.
According to a known packaging method, a first of the two flaps is folded at a right angle on the group of rolls by a first folding device of the packaging unit, and, subsequently, the second of the two flaps is folded, again at a right angle, and superposed on the first flap by a second folding device of the packaging unit.
After folding, the group of rolls and the wrapped film are transported by the conveyor, in a direction transversal to the lifting direction, towards a tunnel equipped with units for closing the package (bottom and tops).
Thus, during movement inside the tunnel, firstly the zone for superposing the flaps is subjected to an operation for stabilising the wrapping material consisting, usually, in a reciprocal sealing of the flaps (as mentioned, further downstream relative to the folding area, that is, during step-like feeding of the above-mentioned pockets) in the tunnel for closing the wrapping film and subsequently also along the two heads formed.
Of particular interest in this invention is the above-mentioned chain or belt conveyor.
This unit comprises (see also patent EP 1 067 048 of the same Applicant as this invention) in a minimum configuration (see
Therefore, the traditional arrangement of the machine outfeed conveyor is such that according to the use until now there is at least one pair of motors which each control a series of belts or chains (two or multiples of two) and fastened to the above-mentioned belts and there are a series of drive carriages at a predefined spacing equal to the extension of the belt or chain divided by the maximum width of the group of products to be retained between the drive teeth.
Each of the motors moves a series of carriages each having a distance equal to the predetermined spacing (format); when a pack is to be contained with widths greater than that of the spacing it is necessary to change it, removing the series of carriages and reducing their number along the extension of the entire path of the chain or belt through a manual operation.
Similarly, in the presence of the second motor which jointly with the first moves a second series of carriages equidistant by the spacing of the first actuator, it is necessary, for a change of spacing, to remove and move or only remove both the carriages of the first actuator and those of the second.
This is because usually in a pair of containment teeth one has the pushing function (upstream relative to a feed direction along the active branch) and one has a containment function (downstream relative to the feed direction).
Starting from this base configuration, the conveyor has, over time, had a series of developments, as required by market needs.
More specifically, a high flexibility of the spacing or format changes between the teeth has been requested to have extremely an small spacing (width with a single product) or a spacing of maximum dimension.
To obtain this, the number of chains and belts and the number of power-driven units which control them has been increased in order to have a control even on individual carriages and not on a plurality of carriages, modifying the spacing of pairs independently.
However, these modifications to the conveyor have given rise to several drawbacks.
A first drawback is due to the long length/extension of the entire ring-shaped path which makes it necessary to increase the distances between the unit and the rest of the outfeed stations.
Moreover, the greater the extension of the group the greater will be the number of carriages in transit, since the extension and the spacing is given by the maximum width of the product to be packaged.
Now, the greater the spacing (and the extension), the greater will be the speed of the power-driven units when it is necessary to package groups of products with small spacing, but if the groups have limited width and the packaging speed requested is high (in view of the length of the path) then the rotation speeds become high, to the detriment of the winding quality and reliability of the machine.
A further drawback currently present in the structure of the unit is due to the need to assemble and dismantle carriages which, according to the format needs, must be carried out manually.
Currently, in fact, the system needs a manual intervention to be able to apply or remove the carriages from the belts or chains by means of a long and laborious mechanical operation.
Another drawback is due to the constructional profile of each tooth, which has the shape of an upturned “L” in which, for each pair of teeth forming the containment pocket, each smaller stretch of “L” (used for connection to the carriage) faces the other one. This configuration creates a problem which arises when the size of the formats (labelled B1 in
In other words, when a configuration is to be made with a size less than the above-mentioned minimum spacing, due to the contact of the upper parts of the two teeth forming the pair, it is necessary to rotate one of the two teeth. This operation must be repeated for all the teeth operating along the annular path.
All these situations result in a significant waste of non-operational time on the machine.
The aim of this invention is to provide a machine for packaging soft products, such as, for example, the rolls of tissue paper products such as rolls of paper for sanitary and/or domestic use which overcomes the above-mentioned drawbacks of the prior art.
More specifically, the aim of this invention is to provide a machine for packaging soft products which can increase and make simpler the size changes of the groups of product being wrapped without modifying the basic structures of the base of the unit for moving the products.
A further aim of this invention is to provide a machine for packaging soft products which is able to reduce the problems of speed reduction for moving the carriage/tooth, in particular for the smaller formats without reducing the productivity and the quality of the packaging of the product.
A further aim of this invention is to provide a machine for packaging soft products which is able to reduce the time for modifying the configurations of the teeth on the carriages, whilst maintaining a high level of safety of drive and containment on the packs of products.
These aims are fully achieved by the machine for packaging soft products according to the invention as characterised in the appended claims.
The features of the machine will become more apparent from the following detailed description of a preferred, non-limiting embodiment of it, with reference to the accompanying drawings, in which:
With reference to the accompanying drawings, in particular
Again with reference to
The feed plane 1 is usually delimited by a pair of flanks.
The machine 100 also comprises a plurality of pulleys 3 positioned at the two ends of the feed plane 1 and connected on at least two power-driven shafts 4, 5 (usually coaxial to each other and completed by a pair of driven shafts, but merely by way of example). Each shaft 4 and 5 is driven independently by at least a first 6 and a second 7 motor.
On the pulleys 3 are wound two pairs of chains or belts 8 (positioned close to the flanks) parallel to and independent from each other, movable along a first direction D8 and a feed direction V8, to define a ring-shaped path having an active linear lower branch 8a facing the feed plane and a non-active linear upper branch 8b.
The machine 100 comprises a plurality of carriages 9 which are connected, alternatively in sequence, to the pairs of motor-driven chains or belts 8 and distributed along the ring-shaped path.
Each carriage 9 supports at least one tooth 10, 11, 12 (normally a plurality of between 2 and 5), projecting towards the feed plane 1 during the passage on the lower branch 8a.
Each tooth 10, 11, 12 is configured for retaining and feeding along the feed plane 1 the groups 2 of products from a receiving compartment 13 to a zone 14 for unloading and releasing the group 2 of products (the unloading and releasing zone 14 coincides with a tunnel for transfer and definitive closing of the packet).
The machine 100 also comprises a control unit 15 (shown here by a block) connected to the motors 6, 7 is configured to control their operation in accordance with variations in the distance between the carriages (9) on the relative pairs of chains or belts 8 as a function of the variations in size of the groups 2 of products.
The machine 100 comprises transfer means 16 for moving one group 2 of products at a time, with a corresponding sheet 17 of wrapping material folded into a “U” shape around the group 2 of products, towards the feed plane 1 and to the receiving compartment 13 defined by a first 10 and a second 11 tooth, along a second direction D16 transversal to the first direction D8.
The transfer means 16 comprise an elevator plate which is able to receive the group of products at a first lower height and lift the group of products to a second upper height corresponding to the receiving compartment defined between the first and second tooth 10 and 11.
As illustrated, along the lower linear branch 8a of the chains or belts 8 there is a number of teeth 10, 11, 12 equal to the number of groups 2 of products positioned or arrived on the feed plane 1, in the operational stretch between the compartment 13 for receiving the group 2 of products and up to the unloading and releasing zone 14.
Each tooth 10, 11, 12 is configured along the operational stretch to define simultaneously both a pushing tooth and a tooth containment when the same tooth 10, 11, 12 is interposed between two groups 2 of consecutive products along the feed plane A.
As illustrated, the lower linear branch 8a defined by the belts or chains 8 has a succession of teeth 10, 11, 12 along the operational stretch, comprising at least, in a minimum operating configuration:
Again as shown in
In other words, the system present on the transfer means comprises a pair of teeth (10 and 11) controlled, in this case, by the corresponding first and second motor 6 and 7. These two teeth contain the group of products in elevation forming the receiving compartment 13.
The same teeth move together and move the group of products by a distance equal to the width of the group of products plus the dimension of the tooth.
This operating parameter has the advantage, with respect to the prior art systems, that the feed step is substantially equal to the size of the pack and not to the step defined mechanically on the machine.
Subsequently, the group of products can be subjected to a lower sealing of the film which surrounds the group of products, whilst it remains between the two teeth until sealing is completed.
In this second movement the tooth labelled 10 (motor 6) moves to the position of the tooth 11 (motor 7) and contains (downstream) the group 2 of products arriving from the receiving compartment 13 which must then be sealed.
During this second movement, the tooth 11 can start pushing the group of products and without any other stop it moves up to the zone 14 for unloading and releasing the group of sealed products where there are units for final closing of the group (typically those for the lateral sealing).
This tooth then completes its stroke positioning behind the teeth which are stationary awaiting their turn to restart the cycle.
This structure makes it possible to reduce the problems of changing the spacing in the machine, the speed reduction for movement of the carriage/tooth (especially for the smallest formats) and rotation of the pushing or containment teeth for the smallest formats.
Basically, the number of compartments defined along the lower linear stretch has each tooth belonging to a carriage which is able to push and simultaneously contain the bundle as a function of the position in which the group of products is located.
Again as illustrated (in particular in
Preferably, each tooth 10, 11, 12 quick comprises means 20 for rapid connection/detachment positioned between the head 18 and the operating contact portion 19 to allow a stable coupling or a separation of the operating portion 19 to/from the head 18.
The rapid connection/detachment means 20 can be, for example, of the type with a bayonet coupling, with pins movable axially and equipped with a spring for maintaining the closed position, etc.
It should be noted that each head 18 has a central seat 18a for housing an end of the operating portion 19 configured to match the central housing seat 18a.
In light of this, between the central seat 18a and the end of the operating portion 19 there are positioned the rapid connection/detachment means 20.
It should also be noted that the configuration of each tooth is like a “T” where the horizontal stretch is extremely reduced in length and allows relative approach between two successive teeth such that it can contain individual formats of extremely reduced width.
Preferably (
This feature makes it possible, in a fast and safe fashion, to modify the geometry of the operating portion 19 as a function of the pulling and pushing needs of the groups of products to be handled.
More specifically, this possibility is increased thanks to the fact that the operating portion 19 of each tooth 10, 11, 12 has the shape of a blade defined by two surfaces of reduced width and two surfaces of large width.
In a first alternative embodiment (
In light of this, the sheath 21 has an external size, of operational contact with the group 2 of products, with dimensions greater than the dimensions of the external size of the operating portion 19 (in both the above-mentioned positions).
According to a second alternative embodiment (
A joining sheath 21 which can be coupled by sliding and interference to the stub 18b and to the operating portion 19 in such a way as to form a complete single operating portion 19.
It should be noted that in this latter alternative embodiment, the sheath 21 may also represent the means 20 for rapid connection/detachment of the operating portion 19 from the head 18.
To complete the structure described above, each carriage 9 comprises:
In light of this, the carriage 9 illustrated has five teeth 10 of which at least four adjustable and a fixed central one for stiffening.
All the teeth present have the possibility of separating the operating portion from the head connected to the carriage.
The machine structured in this way achieves the preset aims thanks to an extremely flexible constructional architecture and which is able to obtain a correct and precise movement on any type of format.
Moreover, thanks to the particular structuring of each tooth, the size changes even with special configurations (non-standard) of the products being processed can be obtained in a rapid, precise manner whilst maintaining a high quality standard of the final product.
Number | Date | Country | Kind |
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102017000130075 | Nov 2017 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2018/058826 | 11/9/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/097378 | 5/23/2019 | WO | A |
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Entry |
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Number | Date | Country | |
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20200391893 A1 | Dec 2020 | US |