The present invention relates to an unreeling assembly, particularly for labeling devices.
Currently, some types of labeling devices for containers such as bottles or jars have means of feeding bands of film to applicator elements, of various types, which are designed to apply the labels to the containers.
The feeding means have, generally, an unreeling assembly, which is typically comprised of two reels of continuous film which are supported by a respective reel support; from one of the two reels, by the action of a traction drum, the continuous film is unreeled and is then cut by a cutting assembly arranged downstream of the unreeling assembly, in order to then be sent to the applicator elements.
Between the “working” reel, i.e. the reel from which the continuous film is unreeled, and the traction drum a plurality of return rolls are normally interposed, as well as a tensioning dandy roll.
The unreeling assembly, in addition to feeding the continuous film to the cutting assembly to be cut, also has the function of correctly tensioning the film, longitudinally, by the action of the tensioning dandy roll.
In some cases, there is an “end of reel” sensor on the unreeling assembly, which sensor is designed to detect when the reel being unreeled is about to be depleted.
In some unreeling assemblies, the reel supports are associated with respective servomotors; in these cases, there are means of detecting the reel radius, which are normally constituted by a sensor (optical, laser or mechanical), which precisely measures the radius of the reel being unreeled so as to make it possible to alter the angular velocity of the reel support as well as, in some cases, to know when the reel is about to be depleted.
In particular, measuring the radius of the reel being unreeled makes it possible to determine the angular velocity of the reel support so as to control the position of the tensioning dandy roll and, consequently, the tensioning of the continuous film being unreeled.
Although the unreeling assemblies described above are widely used, they are not without drawbacks.
In particular, measuring the radius suffers, perceptibly, from possible detection errors or tolerances on the part of the sensors.
In some cases, furthermore, the sensor for measuring the reel radius is positioned close to areas that are the focus of operations (such as changing reels): this leads to the risk that they can undergo impacts or movements with the consequent necessity of performing adjustments, calibrations or replacements.
Lastly, the various sensors used have associated installation, maintenance and running costs.
The aim of the present invention is to solve the above-mentioned problems and overcome the above-mentioned drawbacks, by providing an unreeling assembly, particularly for labeling devices, which is considerably easier and more practical to use than the unreeling assemblies of known types that are used today.
Within this aim, an object of the invention is to make available an unreeling assembly, particularly for labeling devices, that estimates the reel radius with exceptional precision.
Another object of the invention is to provide an unreeling assembly, particularly for labeling devices, that can be made at low cost so as to make its use advantageous also from an economic viewpoint.
This aim, as well as these and other objects which will become more evident hereinafter, are achieved by an unreeling assembly, particularly for labeling devices, comprising a supporting frame for at least one reel of continuous film which is supported by a respective reel support and can rotate about an unreeling axis of the reel and a motorized traction drum, which is designed to unreel said continuous film from said reel of continuous film, where between said reel of continuous film and said traction drum at least one tensioning element is provided, which is movable, with respect to said supporting frame, along a respective movement path, characterized in that it comprises means for estimating the radius of said reel of continuous film as a function of the data related to the angular velocity of said reel, to the speed of the film drawn by the traction drum and to the position of the tensioning element with respect to said supporting frame along the respective movement path.
Further characteristics and advantages of the invention will become better apparent from the following detailed description of some preferred, but not exclusive, embodiments of an unreeling assembly, particularly for labeling devices, according to the invention, illustrated by way of non-limiting example in the accompanying drawings, wherein:
In the embodiments that follow, individual characteristics shown in relation to specific examples may in reality be interchanged with other, different characteristics, existing in other embodiments.
Moreover, it should be noted that anything found to be already known during the patenting process is understood not to be claimed and to be the subject of a disclaimer.
With reference to the figures, the present invention relates to an unreeling assembly, generally indicated with the reference numeral 1, particularly for labeling devices.
The unreeling assembly 1 comprises, in particular, a supporting frame 2 for at least one reel 3 of continuous film 10 which will be cut for making the labels.
The reel or each reel 3 is supported by a respective reel support 4, which is mounted on the supporting frame 2 and can rotate about a respective unreeling axis 100 of the reel 3.
The unreeling assembly 1 is moreover provided with a motorized traction drum 5, for example by means of a respective actuation motor 9, which is designed to unwind the continuous film 10 from the reel 3.
For keeping the tension of the continuous film 10 being unreeled from the reel 3 constant, at least one tensioning element 6 is provided between the reel 3 and the traction drum 5, which tensioning element is movable, with respect to the supporting frame 2, along a respective movement path 200.
According to the invention, the unreeling assembly 1 comprises means 20 for estimating the radius (r) of the reel 3 of continuous film 10 being unreeled as a function of the data related to the angular velocity (ω) of the reel 3, to the speed (v) of the film drawn by the traction drum (5) and to the position (φ) of the tensioning element 6 with respect to the supporting frame 2 along the respective movement path 200.
In particular, the estimation means 20 acquire, for example by means of respective encoders, and calculate the aforementioned data substantially instantaneously where the term instantaneously is used to mean that the acquisition and/or calculation times (for example in the order of a few milliseconds) are negligible in the context of the timing that characterizes the process.
According to a preferred embodiment, the estimation means 20 comprise a “state observer”, i.e. a system of differential equations that estimates the evolution over time of an observable variable, specifically, of the radius (r) of the reel being unreeled.
With specific reference to the embodiment shown in
The values of the speed (v) of the traction drum 5 and of the position (φ) of the tensioning element 6 with respect to the supporting frame 2 along the respective movement path 200 are instead acquired by acquisition means 11.
With reference to the embodiment shown in
According to a preferred embodiment which is shown schematically in
According to a further embodiment shown in
These data acquisition means 11 are associated with a “state observer” 21 which is designed to perform the estimation of the radius (r) of the reel 3 being unreeled.
There is nothing to prevent the control device 23, the control means 22, the acquisition means 11 and the state observer 21 from being all integrated, or being only partly integrated, in the same processor or in different processors.
With reference to the embodiment shown schematically in the figures, downstream of the traction drum 5 there is an applicator 30 for applying labels which are made from the continuous film 10 onto containers to be labeled.
In order to optimize the unwinding of the continuous film 10 from the reel 3, the supporting frame 2 supports, between the reel 3 of continuous film 10 being unreeled and the traction drum 5, a plurality of return rolls 7.
Advantageously, the supporting frame 2 can support at least two reels; between these two reels and the tensioning element 6, there is a joining station 8 which is designed to provide the connection between the end portion of the continuous film 10 unreeled from the reel 3 about to be depleted and the end portion of the film supported by the other reel.
According to a preferred embodiment, the tensioning element 6 can be constituted by what is called a tensioning dandy roll 6a which is supported by the supporting frame 2 so that it can rotate about a respective pivoting axis 101.
In this specific case, the position (φ) of the tensioning element 6 with respect to the supporting frame 2 is constituted by the angular shift of the tensioning dandy roll 6a with respect to a predetermined base position, which is normally measured by means that are per se known such as, for example, an angular potentiometer.
The measurement of this data item is also normally performed in the unreeling assemblies 1 to make it possible to operate on the braking devices or on the servomotors associated with the reel supports 4 in order to keep the tension of the continuous film 10 being unreeled from the reel 3 constant.
According to a possible embodiment, the estimation means 20, and in particular the state observer 21, uses, in order to estimate the radius (r) of the reel 3 being unreeled, the following system of differential equations:
{circumflex over ({dot over (φ)}=k1(ω{circumflex over (r)}−v)−k2({circumflex over (φ)}−φ)
{circumflex over ({dot over (r)}=−k
3
ω−k
1
k
4ω({circumflex over (φ)}−φ)
where:
The present invention also provides a method for estimating the radius (r) of a reel 3 of continuous film 10 being unreeled as a result of the action of a motorized traction drum 5.
In particular, between the reel 3 and the traction drum 5 there is an element 6 for tensioning the continuous film 10 being unreeled.
In more detail, the method comprises a step of estimation, by estimation means (20), of the radius (r) of the reel (3) of continuous film (10) being unreeled as a function of the data related to the angular velocity (ω) of the reel (3) of continuous film (10) being unreeled, to the speed (v) of the continuous film (10) drawn on the traction drum (5) and to the position (φ) of the tensioning element (6) with respect to a supporting frame (2).
The operation of the unreeling assembly 1 according to the invention is evident from the foregoing description.
In particular, the estimation means (20) are capable of acquiring/calculating, instantaneously, the data related to the angular velocity (ω) of the reel 3 of continuous film 10 being unreeled, to the speed (v) of the continuous film 10 drawn by the traction drum 5 and to the position (φ) of the tensioning element 6.
These data are calculated, for example by means of the use of equations which are typically of the differential type, and, on the basis of the characteristics of the geometry of the dandy roll, the radius (r) of the reel 3 is estimated extremely precisely, and without the use of any sensor, so as to optimize the control of the reel 3 itself, thus keeping the tensioning dandy roll 6a, and more generally the tensioning element 6, in the desired position.
All the characteristics of the invention which are indicated above as advantageous, advisable or similar, may also be missing or be substituted by equivalent characteristics.
The individual characteristics set out with reference to general teachings or to specific embodiments may all be present in other embodiments or substitute characteristics in such embodiments.
In practice it has been found that in all the embodiments the invention is capable of fully achieving the set aim and objects.
In particular, it has been found that the unreeling assembly 1 is capable of estimating the radius (r) of the reel 3 very precisely and reliably without using any sensor, with an evident simplification of the unreeling assembly in terms of construction and with consequent reduction in costs.
Furthermore, it has been found that, using the estimation means 20 according to the invention, it is possible to identify very precisely, and without the use of sensors, the moment of depletion of the reel in order to stop the machine or, if there is an automatic joining station 8, in order to perform the connection.
Besides, by not using sensors and instead calculating data related to the unreeling of the continuous film 10 from the reel 3, the estimate of the radius (r) is substantially impervious to any ovalization phenomena of the reel 3 and, therefore, it prevents the possibility of underestimating the radius, such possibility being very frequent in the known unreeling assemblies.
The invention thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the appended claims.
In practice the materials used, provided they are compatible with the specific use, as well as the dimensions and the shapes may be as desired, according to the requirements.
Moreover, all the details may be substituted by other, technically equivalent elements.
The disclosures in Italian Patent Application No. VR2010A000003 from which this application claims priority are incorporated herein by reference.
Where the technical features mentioned in any claim are followed by reference numerals and/or signs, those reference numerals and/or signs have been included for the sole purpose of increasing the intelligibility of the claims and accordingly, such reference numerals and/or signs do not have any limiting effect on the interpretation of each element identified by way of example by such reference numerals and/or signs.
Number | Date | Country | Kind |
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VR2010A000003 | Jan 2010 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP11/50399 | 1/13/2011 | WO | 00 | 7/11/2012 |