This invention relates to a process, and the relating device, for treating the coating of containers. More particularly, it relates to a process, and the relating device, for drying protective coatings on containers, especially bottles made of thermoplastic resin.
Thermoplastic materials, such as PET (polyethylene terephthalate), have been used for some time now to make containers. This is particularly true for food-containing containers, especially drinks. Although said containers can be of different types, they shall be referred to hereinafter generically as bottles, which happen to be the most spread.
Bottles made of thermoplastic materials are definitely convenient in terms of weight, resistance to impact, cost, and similar but also have some drawbacks. For example, said materials are somewhat microporous making, along with the limited thickness of the wall, the bottle permeable to gas. For example, oxygen may penetrate into the bottle modifying the contents through oxidation, and/or carbon dioxide found in many carbonated drinks may escape making the drink less fizzy and attractive.
Many solutions have been put forward to resolve these problems. Firstly, one solution involves increasing the thickness of the bottle wall; unfortunately, this increases production costs and can lead to problems during manufacturing. Secondly, one solution involves using multilayer bottles; however, this increases production costs and complexity. Thirdly, another solution entails depositing a thin layer to act as barrier on the internal wall of the bottles; unfortunately, this also increases costs and complexity.
An apparently simple and effective solution exists to the problem of creating a protective coating capable of acting as barrier to gas exchanges: painting, especially through dipping, the external surface of the bottles.
For example, U.S. Pat. No. 5,658,619 describes a process for coating bottles. This process involves sending bottles to a coating segment where the bottles are gripped and dipped one at a time in one of many containers filled with a coating solution consisting of a resin dispersed in a solvent. Then, after removing the bottles from the coating solution, the bottles are released and sent to a flash-off segment where the solvent of the coating solution is removed from the coating applied to the outer surface of the bottle. After the flash-off process, the bottles are sent to a reticulation station where the resin of the coating is reticulated.
Such a plant is complex and has a few critical points, especially regarding the formation of paint sagging in the detearing phase, during the transfer from the painting station to the flash-off station. Furthermore, eliminating the solvent found in the paint through simple flash-off is a long process that is not well controlled.
Sometimes paints with a water-based solvent are used to reduce costs and limit environmental pollution. Unfortunately, this option hampers drying, requiring long drying times or heating of the bottles at a temperature apt to promote the quick elimination of the solvent. If high outputs are required, said temperature is very near to, if not greater than, the temperature for softening the thermoplastic material of the bottles.
Hence, it is very important to provide a paint-drying system that limits any damage to the bottles and, at the same time, assures treatment methods and limited drying times, after painting, that prevent irregularities in the thickness of the coating.
A simple way of drying said water-based paints is to heat them; for example, by exposing them to infrared radiation (IR).
An infrared-heating plant is described, for example, in patent application PCT/EP00/10540, of this Applicant, although it refers to a plant for conditioning pre-moulded workpieces to be sent to final moulding, meaning that it is used to raise the temperature of said workpieces to one suitable for final moulding. In the aforementioned document, the pre-moulds are conveyed past a series of IR lamps; at the same time, an adjustable airflow at ambient temperature flows, first, around the pre-moulds and, then, around the IR lamps to cool them.
Although this solution is appealing, it concerns non-painted pre-moulds, which must simply be heated at an established temperature using different handling methods and short heating times.
It is an object of this invention to provide a process for drying perfectly a protective layer placed on containers, especially bottles, made of thermoplastic material in order to decrease the permeability of the bottle to gas, which could affect the quality of the contents of the bottle if gas seeps into or out of the bottle.
It is another object of the invention to provide a process for drying the protective layer placed on containers, especially bottles, made of thermoplastic material without overheating the thermoplastic material, which could distort the bottles, and wasting energy.
It is an additional object of the invention to provide a plant for carrying out the aforementioned process.
These and other advantages of the invention shall be readily apparent from the detailed description of the currently preferred embodiments of the invention, given as nonlimiting examples that do not exclude further embodiments and improvements.
This invention refers to a process whereby bottles, which are made of thermoplastic material and held by their aperture by means of evenly distributed specific gripping devices, are dipped into a resin solution in a solvent, which is later evaporated through the flash-off method, in order to place a protective layer on the outer surface of the bottles. The drying process described in this invention comprises the following steps:
Inside the drying furnace, both in the first and second areas, the bottles are positioned horizontally.
The above process is further characterized by the fact that the radiation emitted upward by the heating elements is reflected on the bottles by means of a reflecting device. This reflecting device also lets the airflow that flowed past the heating elements into said second area; in fact, the device is suitably perforated uniformly on 10-30% of its surface (preferably, 15-25%).
The heating elements have an elongated shape and many infrared lamps (IR), preferably arranged in several distinct clusters. The major axis of these heating elements is positioned horizontally.
The temperature of the airflow that brushes against the bottles being fed under the heating elements ranges from 50 to 70° C., and the speed of the airflow flowing around the bottles is between 1.5 and 2.5 m/s; these parameters are controlled so that the temperature of the bottles passing beneath the heating elements is never greater than 65° C.
Then, the airflow, which has been warmed up (to reach a temperature approximately between 60 and 80° C.) by the heating elements, flows (at a speed ranging from 1.5 to 2.5 m/s) around the already treated bottles in the second area of the furnace above the heating elements so that the temperature of the bottles does not exceed 65° C.
The relevant parameters (power emitted by the lamps, airflow, bottle treatment time, and air circulation % in the furnace) are all adjusted so that 75 to 95% of the solvent (ideally 85 to 92%) is removed from the coating through infrared heating in the first area of the furnace, while the remaining amount of solvent is removed through hot air in the second area of the furnace.
In this manner, i.e. by removing only part of the solvent from the coating in the first area of the furnace, it is possible to control very well the temperature of the bottles under the heating elements, minimizing distortions of the bottle wall and resin crystallization.
As was already mentioned, the hot air coming from the first area of the furnace is utilized again in order to remove any residual solvent from the coating in the second area of the furnace, minimizing wasted energy. Furthermore, the air flowing out of said second area is sent back, at least partially, to the first area of the furnace; thus, not only does this further conserve energy but it also helps maintain the desired temperature in said first and second areas of the furnace, promoting excellent process steadiness regardless of ambient temperature.
In addition, part of the cold air drawn from outside the furnace is diverted, before entering the first area of the furnace, in order to maintain the neck of the bottles at a temperature of 55° C. at most.
The bottles are kept in the horizontal position throughout the drying process, and, at least in the infrared furnace, the bottles rotate at a speed between 100 and 300 revolutions per minute.
The infrared lamps are of the medium wave type; the time the bottles take to pass in front of the lamps is included between 15 and 30 sec, preferably 25 sec.
A particular embodiment of the invention shall be described below. This version is given as a nonlimiting example of the scope and scale of the invention, and in conjunction with the following accompanying drawings:
It consists of a chamber (1) delimited by walls (8,15, 17, and 18), comprising the following elements:
During the process, the bottles (4) enter the furnace (2′) near the lamps in a specific position (position 4″), move through the entire furnace in said position, exit the furnace, move upward, and are placed in a specific position (4″). Meanwhile, an airflow (6), which is created and controlled, by devices not shown in the figure, flows from the chamber (12) into the lower area (2) through a duct (19). Once the airflow reaches said area, it is divided by a wall (14) into two parts: a first airflow goes through a wall (11) in order to enter the furnace (2′), control the temperature of the bottles, and cool the devices that emit thermal radiation or heating elements (3); a second airflow flows upward in order to exit the furnace (2′) brushing against a wall (14) in order to keep the neck of the bottles (4) held in the chucks (13) cool.
The first part of the airflow, after cooling the heating elements (3), goes through a wall (10) and flows upward to the upper part of the chamber (1) where it brushes against the bottles in position 4″′, finishing off the paint-drying process, and then flows into the escape chamber (16). In this chamber, the hot airflow is at least partially sent back into chamber 12 through a door (7) in order to regenerate heat and keep the temperature of the furnace (2′) constant.
If there is not enough space lengthwise to handle the required output, instead of the in-line layout, the two segments of the plant can be placed side by side (see
Number | Date | Country | Kind |
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RM02A000452 | Sep 2002 | IT | national |
Number | Date | Country | |
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Parent | 10527225 | Mar 2005 | US |
Child | 13089022 | US |