The present invention relates to a drying system of a coated continuous film and in particular a system equipped with roller conveyor devices of said continuous film.
In detail, the invention relates to a drying system of a coated continuous film equipped with roller conveyor devices of the continuous film that allow easy and rapid removal of the rollers from the system to facilitate cleaning and maintenance operations.
Said drying systems are substantially constituted by a tunnel through which a continuous film coated with a coating, such as adhesive or the like, is fed to heat said coating and allow evaporation of any solvents and humidity contained therein.
Most of these systems are provided internally with a plurality of motorized conveyor rollers adapted to convey said continuous film from an inlet side toward an outlet side, as well as to support said film inside the tunnel.
In prior art systems, said conveyor rollers comprise a cylinder to guide and support the continuous film, if necessary coated with a material with high friction coefficient, supported at the ends by two shafts integral with said cylinder and housed on support means housed in the frame of the system.
In detail, one of said support shafts of the roller conveyor device is also connected to motion transmission means, such as pulleys, sprockets or the like, which transmit motion from motor means to said conveyor roller.
To heat the coating material of the continuous film, for example adhesive or the like, jets or hot air are generally used, directed on the coated side of the film to cause evaporation and subsequent dispersion and expulsion of any solvents or humidity contained in said coating material.
During the air blowing operation, a non-volatile fraction of the coating material of the film may be nebulised by the jets of air and subsequently deposited on the whole of the inner surface of the tunnel and on the various components present inside the tunnel, in particular on the guide cylinders of the conveyor rollers.
Besides soiling the film during conveying thereof, the presence of this deposit of material on the rollers often causes noteworthy problems of alignment of the film inside the machine, above all when the section of continuous film being conveyed inside the tunnel reaches significant lengths (up to ten meters).
To prevent the aforesaid problems, these systems therefore require periodic internal cleaning, in particular thorough cleaning of the conveyor rollers. Currently, said cleaning operations can be carried out using two different methods, both somewhat inconvenient.
With the first method, the rollers are disassembled and cleaning is performed outside the machine.
This solution, which would undoubtedly ensure a satisfactory result from the point of view of cleaning, would however involve a substantial loss of time and unacceptable machine downtime and therefore is almost never used.
In fact, to remove the rollers from the machine it is necessary to dismantle the two roller supports and remove all the motion transmission elements that are connected to one of the two support shafts of said roller.
With the second method, cleaning is performed directly inside the machine without removing the rollers.
Therefore, in this case it is not necessary to disassemble the machine but, due to the small handling spaces inside the machine, the operator performing the operation is obliged to carry out a series of complicated manoeuvres that make it impossible for cleaning to be as accurate as when it is performed outside the machine.
Moreover, these components of the system are usually at a temperature that can even reach 150° C.; consequently the operator must wait several minutes before being able to perform the cleaning operations inside the machine.
In any case, when it is essential to disassemble the rollers, for example to carry out extraordinary maintenance, the time required for their removal from the system considerably affects the total time of the operation and therefore the machine downtime.
In this context, the object of the present invention is to propose a drying system of a coated continuous film that overcomes the aforesaid drawbacks of the prior art.
In particular, an object of the invention is to propose a drying system of a coated continuous film provided with roller conveyor devices of the film that make it possible to facilitate and improve cleaning operations of the conveyor rollers of the coated continuous film, and extraordinary maintenance operations on the system.
In detail, in the drying system of a coated continuous film according to the invention the roller conveyor devices of the continuous film are configured in such a manner as to allow easy removal of the conveyor rollers to allow cleaning operations thereof to be performed outside the machine, or to allow repair or replacement of components of the conveyor rollers.
A further object of the present invention is to provide a drying system of a coated continuous film equipped with roller conveyor devices of the continuous film provided with means adapted to allow the thermal expansions of the conveyor roller caused by the high temperatures inside the drying system.
The objects specified are substantially achieved by a drying system of a coated continuous film equipped with roller conveyor devices of the continuous film comprising a plurality of conveyor rollers supported at the ends by first support means and second support means, said conveyor roller comprising:
In practice, the conveyor roller is separable into two parts with at least one of the two support shafts, in this case the second support shaft, separable from the rest of the roller to facilitate the disassembly and reassembly operations of the conveyor roller from and on the system.
Moreover, the support means are suitably configured to maintain the guide cylinder in contact with the second support shaft and simultaneously to allow thermal expansions of the conveyor roller.
Further characteristics and advantages will be more apparent from the indicative, and therefore non-limiting, description of an example of a preferred, but not exclusive, embodiment of the invention, as shown in the accompanying figures, wherein:
a and 1b are two schematic views respectively in a side and plan view, of a drying system of a coated continuous film, according to the invention;
a and 5B are two details of
With reference to the accompanying
In detail, each roller conveyor device 2 comprises a conveyor roller indicated with 3, first support means 5 and second support means 6 of said roller on the side members 4a and 4b of the drying system 1.
Said conveyor roller 3 in turn comprises a central part constituted by a guide cylinder 7 of a continuous film, preferably made of metal, for example aluminium or steel, whose surface has a series of incisions 8 to improve conveying of the film and limit the cushion effect of the layer or air interposed between said film and the surface of the cylinder.
Instead, two support shafts 9 and 10, respectively supported by the support means 5 and 6, are provided at the ends of said cylinder 7.
In particular, a first support shaft 9 is provided at one end 11 of said cylinder 7 and integral with said guide cylinder, while a seat 13 adapted to house a second support shaft 10 is provided at the opposite end 12 of the guide cylinder 7.
In detail, said second support shaft 10 has a first end 14 configured in a manner substantially complementary to that of the seat 13 formed in the guide cylinder 7, in such a manner as to be able to mate therewith.
Advantageously, said seat 13 and said end 14 have a conical shoulder area 15 to facilitate centering of the second support shaft 10 with the guide cylinder 7, and to prevent possible locking of the end 14 due to radial expansion thereof caused by the increase in temperature.
Said seat 13 is also provided with a slot 16, adapted to house a driving pin 17 projecting radially from the end 14 of the second support shaft 10.
In detail, said slot 16 has a width substantially identical to the diameter of the pin so that that by engaging the slot 16, said pin can transmit motion from the second support shaft 10, driving in rotation the guide roller 7 and the conveyor roller 3 as a whole (
Means for transmitting motion to the conveyor roller 3, such as pulleys 19 or the like, are instead fitted onto the opposite end 18 of the second support shaft 10.
In this way, the conveyor roller 3 is substantially separable into two parts with at least one of the two support shafts, in this case the second support shaft 10, separable from the rest of the roller to facilitate disassembly and reassembly operations of the conveyor roller 3 from and on the system.
In fact, this solution makes it possible to remove only a part of the conveyor roller 3 from the drying system, i.e. the first support shaft 9 integral with the guide cylinder 7, to perform cleaning or maintenance operations outside the machine.
In this way, it is unnecessary to remove all the motion transmission elements, such as the pulleys 19, connected to the second support shaft 10.
For correct operation of the roller conveyor device, the support means 5 and 6 are suitably configured to maintain the guide cylinder 7 in contact with the second support shaft 10 and, simultaneously, to allow thermal expansions of the conveyor roller 3 caused by the high temperatures inside the system.
In particular, axial movement of the second support shaft 10 is prevented in the second support means 6, while the first support shaft 9 is able to move axially in the first support means 5.
With reference to
In detail, said first support flange 20 is mounted on the side members 4b by means of a plurality of bolts 24 inserted in the same number of seats 25 formed in the side members 4b.
The second flange 22 is instead mounted integrally on said first support flange 20 by means of a series of bolts 26 inserted in the same number of seats 27.
The second support shaft 10 is fitted on both bearings 21 and 23 and axial movement is prevented by means of elastic rings 31 or the like.
With reference to
The first support shaft 9 is fitted on the bearing 30 housed in the fourth flange 29 and axial movement is prevented by means of elastic rings 32 or the like. Advantageously, unlike the support means 6, said support means 5 allow said fourth flange 29 to move with respect to the third support flange 28 along the direction of the axis of the support roller 3.
In this way, the support roller 3 can undergo axial thermal expansion which is released onto the end of the first support shaft 9.
To allow perfect centering between the second support shaft 10 and the guide cylinder 7 at all times and to maintain these parts in contact at all times, there are advantageously provided elastic means, adapted to exert a force on said fourth flange 29 of the axis of the support roller 3.
In detail, the fourth flange 29 is connected to the third support flange 28 by means that allow the fourth flange 29 to slide away from or toward the third support flange 28 along a direction parallel to the axis of the conveyor roller 3.
With reference to said
Said means which allow the fourth flange 29 to slide with respect to the third flange 28 comprise a plurality of bushings 35 housed in the same number of seats 36 formed in the fourth flange 29, into which the connection bolts 33 are inserted.
The bushings 35 have a first segment 37 of lesser diameter adapted to house the stem of the bolt 33 and a second segment 38 of greater diameter adapted to house elastic means 39, such as Belleville washers, coil springs or the like. In detail, said elastic means are interposed between the head 40 of the bolts 33 and the shoulder 41 of the bushings 35.
In this way, an elastic force is exerted on the bushings 35, transmitted through contact to the fourth flange 29, which tends to move said fourth flange 29 toward the third flange 28.
In the same way, given that axial movement of the first support shaft 9 prevented with said fourth flange 29, the elastic force is transmitted through said first support shaft 9 to the guide cylinder 7 to the second support shaft 10.
In this way, between the end 14 of the second support shaft 10 and the seat 13 of the guide cylinder 7, there is always a certain contact pressure that allows the two parts of the roller to be maintained connected and centred.
Moreover, on the third support flange 28 there are provided a series of slots 42, level with the fixing bolts 43, to facilitate the operations for disassembly of the support means 5 for removal of the conveyor roller 3 (
In detail, the slots 42 have a widened segment 44 that allows passage of the heads 45 of the fixing bolts 43, in such a manner as to be able to remove the third support flange 28 without having to remove the bolts 43 from the side member 4a of the system.
Moreover, on the edge 46 of the side member 4a of the system there is provided a supporting lip 47, preferably made of a low friction material, such as Teflon or similar plastic materials.
In particular, said lip acts as a support for sliding of the guide cylinder 7, when this is removed from the system to perform cleaning or maintenance operations, preventing contact between the metal material of the side member 4a of the system and the guide cylinder 7.
Operation of the device takes place as described below:
when the drying system of a coated continuous film is switched off, all the components are at room temperature, and the conveyor rollers 3, not thermally expanded, are positioned in the support means as shown in
The temperature inside the system therefore starts to increase, in general up to 150° C., causing thermal expansion of the various components, including the conveyor rollers 3.
If the conveyor roller 3 were to be mounted with axial movement prevented in the support means 5 and 6, this expansion would be prevented with consequent generation of strains damaging both for said support means and for the roller itself.
As a result of the present invention, this expansion is instead compensated by the fact that the fourth flange 29 can slide away from or toward the third support flange 28 along a direction parallel to the axis of the conveyor roller 3.
In this way, all the thermal deformation of the roller is transferred to the end of the first support shaft 9 housed in the support means 5. The presence of the elastic means 39 adapted to exert a force in axial direction on said fourth flange 29 also allows a certain contact pressure to be maintained at all times between the end 14 of the second support shaft 10 and the seat 13 of the guide cylinder 7, to maintain the two parts of the cylinder connected and centred.
During the air blowing operation, due to natural causes or an error by the operator, a certain quantity of coating material of the film may be deposited on the various components of the system, and in particular on the guide cylinders 7 of the conveyor rollers 3.
Due to the present invention the conveyor rollers 3 can be removed easily from the system to perform cleaning operations. In fact, it is sufficient to loosen the fixing bolts 43 of the third support flange 28, rotate said flange to bring the heads 45 of the bolts level with the widened segments 44 of the slots 42, and remove the entire guide cylinder 7 together with the first support shaft and with the support means 5.
After the cleaning or maintenance operations have been completed, the operation can be repeated in reverse order to reassemble the conveyor roller 3 on the system.
The second support shaft 10, to which the pulleys 39 for transmission of motion are connected, instead remains mounted on the system in the support means 6; in this way it is possible to remove even only one roller at a time and keep the machine running during the cleaning operation on each individual roller.
The drying system of a coated continuous film, as described, is susceptible to numerous modifications and variants, all included within the scope of the inventive concept; moreover, all details can be replaced with other technically equivalent elements.
Number | Date | Country | Kind |
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PC2010A000013 | Mar 2010 | IT | national |