The present invention relates to a device and a method for discharging particulate material, for example powder material, granules or capsules, or in general a free-flowing material, such as adhesive material, on a substrate moving along a conveying direction.
The present invention can be used in various fields and is not intended to be limited to a specific field of application. However, the invention has been found to be particularly useful in the field of machines for production of smoking articles, for example for production of filters.
Further known solutions of the above described type are for example disclosed in documents U.S. Pat. No. 7,849,889 B2, US-A-5,875,824, US-A-4,425,107.
The main drawback of these known solutions lies in that the discharging step of the material contained within each pocket of the rotor must be carried out during the time interval in which the pocket is adjacent to its lowermost position, proximal to the conveying line of the filter segments. This obviously poses a limit to the conveying speed of the filter segments and hence to the productivity of the machine.
The above indicated problem is also common to any other application where a device of the above indicated type is provided for discharging particulate material, or in general free-flowing material on a moving substrate. For example, a similar problem is found also in devices of the type illustrated in document U.S. Pat. No. 8,590,582 B2, which relates to the field of machines for production of absorbent sanitary articles.
The object of the present invention is that of solving the above indicated problem, by providing a device and a method for discharging particulate material, for example powder material, granules or capsules, or in general free-flowing material, such as also adhesive material, on a substrate moving along a conveying direction, while ensuring that in any operative condition the discharging operation is carried out efficiently and reliably, without posing any strict limits to the conveying speed of the substrate.
In view of achieving this object, the invention provides a device for discharging particulate material, for example powder material, granules or capsules, or in general a free-flowing material, such as adhesive material, on a substrate moving along a conveying direction, characterized in that it comprises at least one drum rotor having at least one continuous or discontinuous helical track carrying the material to be discharged, said drum rotor being arranged adjacent to the moving substrate, with the axis of the drum rotor substantially parallel to said conveying direction, in such way that the portion of said at least one helical track that is closest to the substrate moves in the conveying direction during rotation of the drum rotor and discharges the material carried thereby on the substrate.
Due to the above indicated feature, the portion of the helical track carrying the material to be discharged which is located adjacent to the substrate follows the latter in its movement along the conveying direction, ensuring that the discharging operation of the material is carried out efficiently and reliably, also when the substrate is moved at a high speed.
In a first embodiment, said at least one helical track is defined by at least a helical channel formed in the outer surface of the rotor drum and arranged to receive the particulate material, said channel being continuous, or defined by a succession of aligned channels or cavities of any shape arranged along a same helical path.
In a first solution, the drum rotor has a cylindrical wall interposed between an inner stator and an outer stator. At least one material feeding inlet is associated with the outer stator and at least a suction chamber is associated with the inner stator, which faces the inner surface of the drum rotor and communicates with a vacuum source, for favouring feeding of the material from said feeding inlet to said at least one helical channel. In the case of this solution, the wall of the drum rotor has a number of holes at the bottom of said at least one helical channel, for the passage of air towards said suction chamber.
According to a further preferred feature, at least one blowing chamber is associated with the inner stator, which faces the inner surface of the drum rotor and is oriented towards said substrate, for favouring discharge of the material on said substrate.
In a variant, said at least one helical track is constituted by a helical channel having a movable or deformable bottom wall and the inner stator is provided on one side facing towards said substrate with a device for pushing radially said movable or deformable wall, in order to favour discharge of the material outwardly on the substrate.
According to a preferred feature, the drum rotor has a plurality of helical tracks which are axially spaced from each other, for simultaneously discharging material on areas of the substrate which are longitudinally spaced from each other in the conveying direction.
In a typical application, the drum rotor is rotated at a speed synchronized with the speed of the moving substrate, so that the portion of each helical track which is adjacent to the substrate moves axially at a speed substantially corresponding to the speed of the moving substrate.
In an alternative embodiment, the above mentioned helical path is constituted by a helical rib carrying adhesive material to be applied on a substrate.
As already indicated, the present invention is of general applicability.
However a specific aspect of the invention relates to the application of the above indicated principles to the field of machines for production of filters for cigarettes or smoking articles in general.
In a variant of the invention, the device comprises a plurality of discontinuous helical tracks, each defined by a plurality of cavities distributed along a respective helical path. In an exemplary embodiment, within each of said cavities there is slidably mounted a piston movable between a retracted position, for receiving the particular material within this cavity, and an advanced position, for discharging the particulate material out of said cavity.
Further features and advantages of the invention will become apparent from the description which follows with reference to the annexed drawings, given purely by way of non limiting example, in which:
In the specific illustrated example, the filter segments F1, F2 which are arranged on the web W have different lengths. Each filter segment is spaced from the filter segment adjacent thereto, so as to define a gap G which is filled with particulate material, such as powder material, granules or capsules.
As shown in
During rotation of rotor R, the particulate material contained within the helical channels E1, E2 is held within these channels, in the way which will became apparent in the following, until the material comes to be at the lower area of the rotor R adjacent to web W, where the material is discharged on the web.
The arrangement of channels E1, E2 on the rotor R and the position of these channels with respect to the sequence of filter segments F1, F2 is selected in such a way that the portion of each channel which is adjacent to the web W comes to be at a gap G between two adjacent filter segments. The speed of rotation of the drum rotor R is synchronized with the speed of advance of web W along direction A, so that the portion of each helical channel E1, E2 adjacent to the web tracks the respective gap G by moving at its same speed. Therefore, the operation for discharging the material into each gap G can be completed within the entire time interval taken by each gap G for going from one end to the other of the drum rotor R. Clearly, this ensures the possibility of carrying out the operation for discharging the material in an efficient and reliable way, without posing any strict limits to the maximum speed of movement of the web W, thereby providing a high productivity of the machine.
A suction chamber CA is associated with the inner stator Si, which communicates with a vacuum source (not shown) and further communicates with a chamber defined between the outer surface of the inner stator Si and the inner surface of the drum rotor R.
As already indicated in the foregoing, the outer surface of the drum rotor R is formed with said plurality of helical channels E1, E2. The bottom wall of each channel is perforated, to enable passage of air towards the suction chamber CA. The suction effect favours and accelerates the step of charging the particulate material into channels E1, E2, while these channels come with their empty portions below hopper T.
Naturally, the provision of a suction system for accelerating the material charging step is preferred, but is not essential. This measure has the advantage of enabling the feeding inlet B to be provided not necessarily above rotor R, but alternatively on one side thereof, if this should be necessary.
In
In the specific example shown in
Furthermore, at an area downstream of the feeding inlet B, with reference to the direction of rotation of rotor R, a rotating brush BR is provided, which is adapted to dose the material on the helical channels E1, E2 of the drum rotor R.
Again in the case of the preferred embodiment shown herein, a blowing chamber CS is associated with the inner stator Si which communicates with a source of pressure and has a communication channel 100 opening in front of the inner surface of the drum rotor R at the lower position of the roller, adjacent to web W. During operation, air blown from chamber CS flows through holes provided on the bottom wall of the helical channels E1, E2 thereby accelerating the discharging step of the material on web W.
Again with reference to
The annexed drawings do not show the details of construction relating to the motors for actuating rotation of the drum rotor R and brush BR, which can be of any known type.
The operation of the above described device is as follows.
The wrapping web W carrying the aligned sequence of filter segments F1, F2, (
Each helical channel E1, E2 receives particulate material from hopper T in the stage in which a portion thereof comes to be facing this hopper. The charging of the material into each channel is preferably favoured by the suction effect due to the suction chamber CA. The portions of the helical channels filled with particulate material coming from hopper T, with the continuing rotation around axis X, come to be at the roller brush Z, which removes excess material from the outer surface of the drum rotor R. As a result of the continued rotation around axis X, brush BR doses the material in channels E1, E2. At the area between brush BR and the material discharging position, the material is held within channels E1, E2 by a wall of the outer stator Se which surrounds rotor R and/or due to the suction effect of the suction chamber CA (in this case communication channels are provided also in this area of the inner stator Si).
As soon as the material contained in each helical channel E1, E2 comes to be at the discharging position, it is discharged on the moving web W, flowing through the longitudinal slot 102 of wall 101. This discharging action is preferably favoured by the blowing action due to the blowing chamber CS, even if this measure is not absolutely essential (as the provision of the suction chamber CA).
As already indicated in the foregoing, the configuration of the drum rotor R and in particular the configuration and the arrangement of the helical channels, E1, E2, etc. and the speed of rotation of the rotor R are such that the portion of each channel which is adjacent to the web W moves progressively in the conveying direction A of web W at the same speed as the web, thus being always facing a respective gap G between two adjacent filter segments. In other words, the portion of the helical channel which discharges material on the web W tracks a respective gap G in its movement along direction A. Therefore, filling of each gap G can be performed during the time necessary for said gap to move in the A direction from one end to the other of the drum rotor R. This represents the main advantage of the present invention, from which the possibility derives of insuring a complete and reliable discharge of the material with no need of posing limits to the maximum conveying speed of web W.
In an alternative embodiment, in order to favour the material discharging step, one or more helical channels are provided, each having a movable or deformable bottom wall. In this case, the inner stator is provided on one side adjacent to the discharging area of the material with a device for pushing said movable or deformable wall radially outwardly, in order to push the material contained within the helical channel out of the channel and over the substrate. In an actual embodiment of this solution, which is diagrammatically shown in
Naturally, while the principle of the invention remains the same, the details of construction and the embodiments may widely vary with respect to what has been described and illustrated purely by way of example, without departing from the scope of the present invention.
Number | Date | Country | Kind |
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TO2014A001004 | Dec 2014 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2015/059251 | 12/1/2015 | WO | 00 |