The present invention relates to a production plant for producing preforms or containers made of thermoplastic material, for example made of PET, and in particular to a cooling apparatus employed in said plants.
The production of a significant number of thermoplastic containers, in particular of bottles, is a process which starting from the raw material, which generally is polyethylene terephthalate or PET, allows obtaining finished containers having a shape—even a particularly complex shape—adapted to the most varied needs of the market and particularly lightweight and also resistant when subjected to strong pressures at room temperature.
The passage from PET in the raw state in the form of granules to plastic container can be achieved by choosing a single-stage process or a two-stage process.
The single-stage process is performed with a single production plant in which the passage from PET granules to preform by means of a mold injection step, and the passage from preform to plastic container by means of the stretch-blowing step, occurs continuously, without letting the preform completely cool to room temperature. Thereby, the preform still maintains part of the latent heat remaining from the injection step, with significant energy saving, because the preforms require less heat to then be brought back to the temperature suitable for blowing with respect to the case in which they are to be reheated starting from room temperature. Instead, a so-called “two-stage” process is performed in two generally, but not necessarily, separate plants: one production plant performs the first part of the production process of the containers with the passage from PET granules to preform, that is, it performs the injection step of the PET preforms into injection molds. The second part of the process, which transforms the preform into the final container in a blowing machine with the stretch-blowing technique, which is the one generally used today to blow PET containers, is performed in the other production plant. The two-stage process may also be performed in the same production plant, which provides injecting preforms and blowing the same into containers, but the two operations are performed at two separate times. The preforms are first cooled in special cooling plants up to reaching room temperature, to then be stored while waiting to be introduced into appropriate ovens to bring them back to the temperature required to perform the blowing process typical of the thermoplastic used or required for the stretch-blowing, in the event PET is used.
So-called stars comprising a rotatable wheel provided with a series of grippers having extendible arms equipped with jaws may be employed for transporting the preforms or final containers in plants consisting of rotary carousels. Certain problems concerning this type of production plant for producing PET preforms or containers relate to the need to provide an increased automation capability, increased reliability, an increase in the transfer speed of the preforms from one station to the other, the decrease in maintenance times, and above all the decrease in production times. In order to increase the production capacity of the preforms, there is a need to make use of highly automated systems, and there is a need to decrease the times the preforms remain in the molding modules and the times required for a first cooling of the preform to make it sufficiently solid on the outside so that it can be picked by the grippers of the transfer stars or wheels without the risk of deformation. Minimizing these times may result in the risk of the formation of crystallinity zones if a system for quickly transferring the preforms to an efficient cooling apparatus where the preform may be quickly brought back to room temperature, is not available. Therefore, the need is felt to make new plants with rotary machines for producing preforms or containers, in particular made of PET, in order to meet the market needs of increasing productivity. And therefore, for the reasons mentioned, also new and more efficient cooling plants are needed.
It is the object of the present invention to provide a rotary cooling apparatus for a production plant for producing thermoplastic preforms or containers, in particular PET, which solves the above-mentioned problems. One of these problems in particular relates to the cooling times of the preforms or containers, such as for example test tubes.
The solution is a rotary cooling apparatus which can be employed in production plants of preforms or containers, such as test tubes, with a high production speed, that is, a rotary cooling apparatus of preforms or containers made of thermoplastic material, in particular made of PET, which comprises:
Another aspect of the invention provides a production plant for producing preforms or containers made of thermoplastic material comprising the aforesaid rotary cooling apparatus, wherein said rotary cooling apparatus is arranged downstream of a rotary injection molding machine, and wherein a transfer wheel is provided between said rotary injection molding machine and said rotary cooling apparatus.
A further aspect of the invention relates to an operating method of the rotary cooling apparatus, wherein a transfer wheel is provided upstream of the rotary cooling apparatus, the method at full speed comprising, for each cooling device, the following steps during the rotation of the carousel:
Advantageously, the solution of the invention allows:
The dependent claims describe preferred embodiments of the invention, thus forming an integral part of the present description.
Further features and advantages of the invention will be more apparent in light of the detailed description of a preferred, but not exclusive, embodiment described according to an apparatus for producing plastic containers of the injection or injection-compression type, shown by way of non-limiting example, with the aid of the accompanying drawings, in which:
With reference to
The rotary cooling apparatus 10 is arranged downstream of a rotary injection molding machine 11, for example but not necessarily, a rotary injection-compression molding machine.
A transfer wheel 12 is provided between the rotary injection molding machine 11 and the rotary cooling apparatus 10. Any technical solution for unloading the cooled preforms or containers may be provided downstream of the rotary cooling apparatus 10. For example, one or more unloading wheels 13 may be provided, as shown in
A linear type of unloading device or any other suitable unloading device, for example one or more containers for receiving the cooled products, can be provided as an alternative to the unloading wheels 13.
Preferably, an optical control system of the individual preforms or of the individual containers downstream of the rotary cooling apparatus 10, is provided. In the specific example in
In particular, the guide element 6 may be a continuous or non-continuous annular element, that is an annular element which is closed or open in a portion thereof, concentric to carousel 1, and provided with areas at different heights.
The at least one picking and releasing device 5 is adapted to translate upwards or downwards transversely to the radial direction, for example perpendicularly to the radial direction, by means of the cooperation thereof with the fixed guide element 6 during the rotation of carousel 1.
For example, each picking and releasing device 5 comprises a support structure 14 which can slide along a substantially vertical guide 15 fastened to the structure of the carousel. Such a support structure 14 is provided, preferably at the upper end thereof, with a roller or lifter element 16 which, during the rotation of carousel 1, by sliding or following the guide element 6, causes the upwards or downwards translation of the corresponding picking and releasing device 5. The support structure 14 instead is provided with grippers 18, preferably at the lower end thereof. Optionally, at least one cooling device 3 and at least one corresponding picking and releasing device 5 are arranged, and therefore define, a cooling module 2 of the rotary cooling apparatus.
In the event of the presence of cooling modules 2, at least one guide 15 is fastened on each cooling module.
In the example in
In other variants, less than three or more than three cooling devices 3 and respective picking and releasing devices 5 may be provided for each cooling module 2. A single cooling device 3 and a single corresponding picking and releasing device 5 may also be provided.
As shown in the example in
Preferably, the plurality of cooling tubes 4 of each cooling device 3, which substantially are adjacent one with respect to the successive one along the radial direction, is arranged on a base 7 which slides on a guide 9 in turn integrally fastened to the cooling module 2.
Therefore, the movement device 17, for example at least one motor with related transmission, imparts the translation motion along the direction Y which is radial to base 7.
The cooling tubes 4 each define a substantially vertical axis thereof, which is perpendicular to the longitudinal axis defined by base 7.
Each cooling tube 4 is, for example, provided with an internal circuit for a cooling fluid, for example water, and with an air suction duct to facilitate the introduction of the preform into the cooling tube when released by the picking and releasing device 5.
The base 7 of each cooling device 3 is provided with channels for the cooling fluid which are connected to the internal circuit of each cooling tube, and is provided with a channel for the air connected to the suction duct of each cooling tube 4. In particular, at least one inlet channel and at least one outlet channel for the cooling fluid are provided in the base 7.
Below is a description of an operating method of the rotary cooling apparatus of preforms according to the invention, considering that a transfer wheel 12 is provided upstream of the rotary cooling apparatus 10 and an unloading wheel 13 is provided downstream of said rotary cooling apparatus 10. Containers, for example test tubes, may be cooled in place of the preforms.
As mentioned above, a linear type of unloading device or any other suitable unloading device, for example one or more containers for receiving the cooled products, may be provided as an alternative to the unloading wheel 13.
The cooling tubes 4 in
The operating method at full speed of the rotary cooling apparatus 10 comprises, for each cooling device 3, during the rotation of carousel 1, the following steps (
Receiving position means the position of the cooling tube below the corresponding picking and releasing device 5, in particular the position of the cooling tube 4 when the latter is coaxial to the area enclosed by the grippers 18, in closed position, of the picking and releasing device 5.
The picking from the transfer wheel 12 and the releasing into the cooling tubes 4, for example from the first to the nth tube, of the respective preforms to be cooled, are provided in a starting step of the apparatus of the invention, which precedes the operation at full speed. An example of this starting step is shown in
Preferably, picking the preforms, or the containers, from the transfer wheel 12 occurs at a first height; releasing the preforms into the respective cooling tubes 4 occurs at a second height, lower than the first height; picking the preforms from the respective cooling tube 4 occurs at a third height, lower than or equal to the second height; and releasing the preforms to the unloading wheel 13, or other suitable unloading device, occurs at a fourth height, higher than the second height. The first height and the fourth height may be equal to each other.
With reference to the plant in
The picking and releasing devices 5 are always free of preforms in stretch AB of the rotary apparatus 10 defining an acute central angle α. At full speed operation, each cooling device 3 in this stretch AB has only one empty cooling tube.
Number | Date | Country | Kind |
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102020000032357 | Dec 2020 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2021/062060 | 12/21/2021 | WO |