This invention relates to a machine and a method for forming containers from blanks.
These containers are used for packaging small-sized loose articles. For example, these containers may be used in the food industry for packaging loose confectionery products and the like. Generally speaking, these containers, for example, are shaped in such a way as to have a cross section that tapers from an upper portion of the container to a bottom portion of the container.
As is known, machines for forming containers are equipped with a conveyor provided with a plurality of pockets adapted to receive blanks (for example, tubular blanks, whether flat or pre-folded and partly glued) to move them along a path through operating stations which form them.
In this context, these containers have at least a main body defined by four side walls, a top opening (with upper end flaps) and a bottom opening (with lower end flaps). This container may be made of cardboard or other material suitable for containing the aforementioned small-sized loose articles.
Generally, the blanks from which these containers are made are worked with suitable means to make creases and/or lines of weakness on them so that they are more compliant during final folding.
Next, the blank is conveyed to a part of the machine where two side rails start folding two opposite walls and two folders fold the other two walls. The folders are provided with elements that capture one of the panels of the blank and push it in controlled manner so it is folded correctly.
At the end of this operation, the walls are in a folded position, defining the aforementioned cross section from the upper portion to the lower portion. At this point, the lower end flaps can be glued so as to hold the blank in this position.
Next, the container is filled and lastly the upper end flaps are also glued in order to close the container thus formed.
Disadvantageously, prior art machines and methods like the ones described above lack precision and/or are slow in operation to ensure optimum forming to prevent the container from opening during one of the later forming operations.
In other words, state of the art machines are based on a sequence of operations which, if not adequately coordinated, lead to non-optimal formation of the container or possible damage to it, making it unsuitable for containing the above mentioned loose articles.
The technical purpose of this invention is therefore to provide a machine and a method for forming containers from blanks—for example, tubular blanks—which allow overcoming the above mentioned disadvantages of the prior art.
The aim of this invention is therefore to provide a machine and a method for forming containers from blanks to allow containers to be formed quickly and precisely.
The technical purpose indicated and the aim specified are substantially achieved by a machine for forming containers from blanks, comprising the technical features described in one or more of the appended claims 1 to 10, and by a method for forming containers from blanks, comprising the technical features described in one or more of the appended claims 11 to 13. The dependent claims correspond to possible embodiments of the invention.
The technical purpose and aim specified are substantially achieved by providing a machine for forming containers from blanks and comprising a plurality of shaping hoppers, each of which has a top mouth and a bottom mouth, opposite to each other and open to define a shaping through channel, and which are configured to receive respective blanks at the top mouth. Each hopper is internally provided with folding features giving the shaping channel a tapered cross-sectional shape in order to cause progressive folding of edges and/or side walls of the blank when the blank is inserted into the hopper. The machine also comprises an endless conveyor defining a feed path and on which are mounted in succession the hoppers and a plurality of pushing elements, each operating on one of the hoppers to push the respective blank into the shaping channel towards the bottom mouth so as to determine the progressive folding of edges and/or side walls of the blank and in such a way that end flaps of the blank protrude respectively from the top mouth and the bottom mouth. The pushing elements are movable in such a way as to follow the respective shaping hoppers along at least a stretch of the feed path and have a to-and-fro operating movement towards and away from the respective hopper along a direction transverse, preferably perpendicular, to the feed path. The machine also comprises folding means disposed on the feed path downstream of the pushing elements and configured to fold the end flaps of the blank inside the respective hopper, thus producing, respectively, a top closure and/or a bottom closure of the blank.
Preferably, each pushing element comprises a plunger, operating on the hoppers to push the respective blank into the shaping channel in such a way that end flaps of the blank protrude from the bottom mouth, and a pushing frame, operating on upper end flaps of the blank in such a way that they protrude from the top mouth.
Preferably, the plunger has a tapered shape, and still more preferably, is shaped to match the shaping channel.
Preferably, the machine also comprises positioning means for positioning the blanks and movable in such a way as to follow the respective shaping hoppers along at least a stretch of the feed path.
Preferably, the machine is also provided with a filling station for filling the loose articles into the containers and located upstream of the folding means which are configured to close the top of each blank.
Advantageously, the machine is capable of forming the container without breaking any of the components of the blank.
Advantageously, the action of the pushing elements is such as to form the container precisely and at high speeds.
The technical purpose and aim specified are substantially achieved by a method for forming containers from blanks in a machine as described above, comprising the following steps:
Further features and advantages of the present invention are more apparent in the indicative, hence non-limiting description of an embodiment of a machine and method for forming containers from blanks.
The description is set out below with reference to the accompanying drawings which are provided solely for purposes of illustration without restricting the scope of the invention and in which:
With reference to the accompanying drawings, the numeral 1 denotes in its entirety a machine for forming containers C from blanks S; reference is made hereinafter to pre-glued tubular blanks S without loss of generality.
By “tubular blanks” S are meant blanks, as shown for example in
Shown by way of example in
The blank therefore has a number of edges SP and several fold lines P located in proximity to the edges and to the lines joining the end flaps to the side walls L.
Once the container C has been formed, the bottom end flaps A (that is, the end flaps A located at the bottom opening AI) define a bottom closure CF of the container C.
Once the container C has been formed, the top end flaps A (that is, the end flaps A located at the top opening AS) define a top closure CT of the container C. Further, the top end flaps A may also be provided with additional fold lines P suitable for making the top closure CT.
The term “container” C is used to denote a box, as shown, for example, in
The main body S1 has a top closure CT at the top of it and a bottom closure CF at the bottom of it. The main body S1, the top closure CT and the bottom closure CF thus define a containing space in which to hold loose articles, specifically small-sized loose articles. For example, the container C is suitable for use in the food industry for packaging loose confectionery products and the like. The top closure CT can be opened by a user to gain access to the containing space in order to take out the loose articles contained therein.
The machine 1, as shown in
As shown in
Each hopper 2 is internally provided with folding features 3 giving the shaping channel 2c a tapered cross-sectional shape. In other words, the inside walls of the hopper 2 are provided with recesses and/or protuberances defining the folding features 3 which, in the example illustrated, give the shaping channel 2c a cross-sectional shape that tapers from the top mouth 2a to the bottom mouth 2b. The folding features 3 are made in such a way as to cause the edges SP and/or the side walls L of the tubular blank S to be progressively folded when the tubular blank S is inserted into the hopper 2. In other words, during insertion of the tubular blank S into the hopper 2, the folding features 3 press against the edges SP and/or the side walls L in such a way as to give the main body S1 of the container C the tapered cross-sectional shape.
In an embodiment not illustrated, the shaping channel 2c may have a constant or tapered cross-sectional size.
The machine 1 also comprises a conveyor (not illustrated) defining a feed path T of the hoppers 2. The hoppers 2 are mounted one after the other in succession on the conveyor so they are transported along the feed path T. The conveyor moves the hoppers 2 continuously along the feed path T.
Preferably, the machine 1 also comprises a guide rail 4 which at least partly defines the feed path T in conjunction with the conveyor. More specifically, the guide rail 4 defines a curved stretch of the feed path T of the hoppers 2 [m1][BC2] (hence of the tubular blanks S).
Preferably, the feed path T is defined by two straight stretches and two curved stretches, forming a path having the shape substantially like that of a caterpillar track. Preferably, at the curved stretches, the conveyor is provided with suitable sprockets (not illustrated).
The machine 1 also comprises a plurality of pushing elements 5, each operating on at least one of the hoppers 2 to push a respective blank into the shaping channel 2c towards the bottom mouth 2b. More specifically, the pushing elements 5 operate on the hoppers 2 in such a way as to cause the edges SP and/or the side walls L of the tubular blanks S to be progressively folded. The pushing action of the blank into the shaping channel 2c towards the bottom mouth 2b causes the end flaps A of the blank to protrude from the top mouth 2a and the bottom mouth 2b of the hoppers 2. In other words, following the pushing action applied by the pushing elements 5 on the tubular blanks S, the upper end flaps A protrude from the top mouth 2a of a respective hopper 2 and the lower end flaps A protrude from the bottom mouth 2b.
More specifically, the pushing elements 5 are movable in such a way as to follow the respective shaping hoppers 2 along at least a stretch of the feed path T. Preferably, and as shown in the example embodiment of
As the pushing elements 5 follow the respective hoppers 2, they have a to-and-fro operating movement towards and away from the respective hopper 2 along a direction transverse to the feed path. Preferably, the to-and-fro operating movement is performed perpendicularly to the feed path T.
As shown in the accompanying drawings, the to-and-fro operating movement is performed coaxially with the shaping channel 2c.
In the embodiment of the accompanying drawings, the pushing elements 5 are movable on a closed path which is at least partly superposed on the feed path T. Preferably, the closed path has a circular shape. In the embodiment, the closed path is superposed on a circular stretch of the feed path T.
In an embodiment not illustrated, the pushing elements 5 are movable over a larger portion of the feed path T than in the embodiment described above. Preferably, in this example embodiment which is not illustrated, the closed path may be superposed on the entire feed path T of the hoppers 2.
As shown in
The plunger 5a operates on the hoppers 2 to push the respective tubular blank S into the shaping channel 2c. That way, the plunger 5a, acting in conjunction with the shaping channel 2c, is able to give the main body S1 the tapered cross-sectional shape described above (and illustrated in
The plunger 5a has a tapered shape. Preferably, a top portion 5c of the plunger has a tapered shape.
Preferably, the plunger 5a (that is, the top portion 5c thereof) is shaped to match the shaping channel 2c.
For example, and as shown in the embodiment of
Also imaginable are plungers 5a with other shapes, depending on the shapes of the folding features 3 of the hoppers 2. In other words, based on the container C to be made, the shaping channel 2c and the plunger 5a (that is, the top portion 5c thereof) are shaped differently to those described above.
The pushing frame 5b operates on the tubular blank S, specifically on the upper end flaps A in such a way that they protrude from the top mouth 2a. More specifically, the pushing frame 5b acts on the upper end flaps A in such a way that they are folded towards an outer portion of the tubular blank S. In the example embodiment, the pushing frame 5b has four walls defining a channel which passes through top and bottom openings defined by the walls of the pushing frame 5b itself. Other embodiments of the pushing frame 5b are imaginable as a function of the shape of the container C to be formed (that is, of the tubular blank S). More specifically, the shape of the pushing frame 5b may depend in particular on the number and/or distribution of the upper end flaps A defining the top closure CT of the container C.
The plunger 5a and the pushing frame 5b are configured in such a way as to move by translation relative to each other. More specifically, the relative translational movement is performed in such a way that the pushing frame 5b causes the upper end flaps A to protrude after or at the same time as the blank S is pushed into the shaping channel 2c by the plunger 5a.
In use, the plunger 5a pushes the tubular blank S into the shaping channel 2c and after that (or at the same time), the pushing frame 5b operates to make the upper end flaps A protrude outside the main body S1 [m3] [BC4] of the tubular blank S.
Preferably, the plunger 5a and the pushing frame 5b are movable independently of each other. The term “independent” means that the pushing frame 5b is moved by an actuator that is distinct from the actuator that is configured to move the plunger 5a. In other words, the up and down movement of the plunger 5a is driven independently of the up and down movement of the pushing frame 5b. In other words, in a condition of use, although the plunger 5a is moved before or at the same time as the pushing frame 5b, the pushing frame 5b might move before the plunger 5a.
As shown in the accompanying drawings, the pushing frame 5b is disposed coaxially around the plunger 5a. Preferably, the size of the pushing frame 5b is such as to allow the plunger 5a (that is, the top portion 5c thereof) to pass through the channel defined by the walls of the pushing frame 5b. In other words, the dimensions of the channel defined by the walls of the pushing frame 5b are greater than or approximately equal to those of the plunger 5a (that is, of the top portion 5c thereof).
In the embodiment of the accompanying drawings, the machine 1 also comprises positioning elements 6 for positioning the blanks S.
The positioning elements 6 have a transverse cross section that is substantially C-shaped so they can correctly hold respective tubular blanks S to position them correctly at respective hoppers 2 and pushing elements 5.
The positioning elements 6 are movable in such a way as to follow the respective shaping hoppers 2. More specifically, the positioning elements 6 follow the respective hoppers 2 along at least a stretch of the feed path T. The positioning elements 6 therefore also follow the pushing elements 5.
Preferably, the positioning elements 6 are movable on a respective closed path which is partly superposed on the closed path of the pushing elements 5. As shown in the accompanying drawings, the positioning elements 6 may be superposed on the closed path of the pushing elements 5 in an initial portion where the pushing elements 5 follow the hoppers 2 being transported by the conveyor.
Preferably, the respective closed path of the positioning elements 6 is circular.
Each positioning element 6 is movable along the respective closed path between an engaged configuration, where it engages the respective tubular blank S, and a disengaged configuration.
By “engaged configuration” is meant that the positioning element 6 fits around the respective tubular blank S in such a way as to engage a respective pushing element 5. In other words, the engaged configuration corresponds to a respective position where the positioning element 6 keeps the tubular blank S aligned with the respective hoppers 2 and with the pushing elements 5. The engaged configuration is maintained until the pushing elements 5 start pushing the tubular blank S into the shaping channel 2c. In the engaged configuration, the positioning elements 6 allow holding the tubular blank S in such a way as to overcome the shape memory of the tubular blank S which would cause it to open and return to its flat blank configuration.
By “disengaged configuration” is meant a configuration in which the positioning element 6 allows the respective pushing element 5 to push the tubular blank S into the shaping channel 2c. In other words, the disengaged configuration corresponds to a position where the positioning element 6 is spaced from the respective blank S so that the pushing element 5, now engaged with the tubular blank S, can push the tubular blank S into the shaping channel 2c without interference.
In other words, the engaged configuration corresponds to a configuration where the positioning element 6, in the portion of the respective closed path superposed on the feed path T of the hoppers 2 and on the closed path of the pushing elements 5, is aligned with (that is, coaxially positioned) relative to the hoppers 2 and to the pushing elements 5, while the disengaged configuration corresponds to moving the positioning element 6 away so it is not aligned with the hoppers 2 and the pushing elements 5.
The machine 1 also comprises folding means (not illustrated) located on the feed path T, downstream of the pushing elements 5. The folding means are configured to fold the end flaps A of the tubular blank S which has been inserted into the hopper 2, to make the top closure CT and/or the bottom closure CF of the tubular blank S.
The folding means may be located in the same portion of the feed path T so that they are aligned and can fold both the lower and the upper end flaps A while the hoppers 2 move forward.
Alternatively, the folding means may be located in different portions of the feed path. For example, the lower folding means, which are configured to fold the lower end flaps A to make the bottom closure CF, may be located upstream of the upper folding means, which are configured to fold the upper end flaps A to make the top closure CT, or vice versa.
Preferably, the machine 1 is also provided with gluing means (not illustrated), located upstream of the folding means (or of each folding means) and configured to glue portions of the upper and lower end flaps A. That way, once the folding means have folded them, the end flaps A are glued to each other to form the top closure CT and the bottom closure CF.
Preferably, in a further embodiment not illustrated, the machine 1 also comprises a filling station for filling the loose articles into the containers C and located upstream of the upper folding means which are configured to make the top closure CT of the tubular blank S. In other words, the filling station is configured to fill the tubular blank S whose lower end flaps A have already been folded by the bottom folding means to form the bottom closure CF. In other words, the filling station is located upstream of the upper end flaps A and downstream of a folding means for folding the lower end flaps.
In use, the machine 1 described above is fed with the tubular blanks S in a portion of the feed path represented by the IN arrow I in
At this point, as shown for example in
More specifically, the pushing element 5 starts its movement by advancing towards the respective hopper 2 while at the same time following the hopper 2. The pushing element 5 moves down towards the hopper 2 until its engages the respective tubular blank S and is inserted into it. Preferably, in the embodiment illustrated in the accompanying drawings, the plunger 5a (that is, the top portion 5c thereof) is inserted into the main body S1 of the tubular blank S through the top opening AS. Where the presence of the positioning elements 6 is contemplated, once the pushing element 5 has engaged the respective tubular blank S, the positioning elements 6 move away from the tubular blank S, passing from the engaged configuration to the disengaged configuration.
Next, the plunger 5a and the pushing frame 5b move in such a way as to push the tubular blank into the shaping channel 2c. Alternatively, the pushing frame 5b may apply the pushing action after the pushing action applied by the plunger 5a.
More specifically, the plunger 5a (that is, the top portion 5c thereof) pushes the main body S1 against the folding features 3 of the hoppers 2 in such a way as to give the tubular blank S the tapered cross-sectional shape, shown in
Advantageously, the to-and-fro movement of the pushing elements 5 allows the tubular blank S to be formed quickly and precisely. More specifically, the pushing action allows inserting the tubular blank S into the respective hopper 2 in such a way that it is held firmly and in a compressed state as it moves along the feed path T so as to give the main body S1 the tapered cross-sectional shape by overcoming the shape memory which very often makes the processes of prior art machines difficult and/or relatively imprecise.
After the tubular blank S has been inserted into the shaping channel 2c to obtain a tubular blank S like the one shown, for example, in
Preferably, if the filling station is present, first the bottom closure CF is formed, then the main body S1 is filled and, after that, the top closure CT is formed, thereby making the full container C.
At this point, the container C is extracted from the respective hopper 2 in the proximity of the OUT arrow U, shown by way of example in
This invention also has for an object a method to form containers C from pre-glued tubular blanks S. The method is carried out in a machine 1 like the one described in the foregoing (that is, in accordance with one of the embodiments described above).
The method comprises a step of feeding a pre-glued tubular blank S to a respective hopper 2. The hopper 2 has a top mouth 2a and a bottom mouth 2b, opposite to each other and open to define a shaping through channel 2c, and internally provided with folding features 3 which give the shaping channel 2c a tapered cross-sectional shape.
Preferably, the method may also comprise a preliminary step of folding and gluing a flat blank in order to obtain the tubular structure of the tubular blank S. In other words, the method may comprise a step of making a tubular blank S that is pre-glued prior to the step of feeding the tubular blank S to the respective hopper 2.
Next, the method comprises moving the hopper 2, provided with a tubular blank S, along a feed path T.
The method also comprises pushing the tubular blank S into the shaping channel 2c of the hopper 2 by means of a pushing element 5 which is movable in such a way as to follow the hopper 2 and which has a to-and-fro operating movement towards and away from the hopper 2 along a direction transverse, preferably perpendicular, to the feed path T. This pushing action allows determining a progressive folding of edges SP and/or side walls L of the tubular blank S and in such a way that end flaps A of the tubular blank S protrude respectively from the top mouth 2a and bottom mouth 2b.
The step of pushing preferably comprises pushing the tubular blank S into the shaping channel 2c by means of a plunger 5a, having a tapered shape, preferably matching the shaping channel 2c.
The step of pushing preferably comprises folding the end flaps A by means of a pushing frame 5b after, or at the same time as, the step of pushing with the plunger 5a.
The sub-steps of pushing and folding are accomplished by moving the plunger 5a and the pushing frame 5b relative to each other.
The method also comprises folding the end flaps A of the tubular blank S to produce, respectively, a top closure CT and/or a bottom closure CF by means of folding means disposed along the feed path T downstream of the pushing elements 5.
The method may also comprise the steps of housing a tubular blank S in a positioning element 6 and moving the positioning element 6 so it follows a respective hopper 2. The movement is performed along at least one stretch of the feed path T. That way, the method allows keeping the tubular blanks S aligned with the respective hoppers 2.
Moreover, the method comprises moving the positioning element 6 away from the feed path T once the pushing element 5 has started the step of pushing. Thus, the method allows the tubular blank S to be pushed into the shaping channel 2c without interference.
Preferably, the method also comprises a step of filling the tubular blank S, carried out between a step of folding the lower end flaps A and a step of folding the upper end flaps A.
Advantageously, this invention is capable of overcoming the disadvantages of the prior art.
Advantageously, the machine 1 is capable of forming containers C from tubular blanks S, at high speed and with a high degree of precision.
More specifically, the machine 1 is capable of implementing this forming process with a reduced number of steps compared to the machines and/or the methods used in the prior art and is also capable of solving the problem of imprecision caused by the shape memory of the tubular blanks S themselves.
Advantageously, the machine 1 is able to prevent damage to the tubular blanks S being formed and thus offers a sure economic advantage.
Number | Date | Country | Kind |
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102019000014418 | Aug 2019 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/056995 | 7/24/2020 | WO |