RO119784B1 - Recipient for storing a liquid meant for alimentary consumption and process for making the same - Google Patents

Abstract

The invention relates to a recipient for storing a liquid meant for alimentary consumption, which comprises an active layer of polyethylene, which comprises silver ions, said layer being protected by an outer layer, made up only of polyethylene, which consists in that the active layer has a thickness of 0.05...1 mm and has a content of 0.005...0.3% by weight of a powder containing Ag+ ions with biocide activity, deriving from AgCl, deposited on an inert TiO2 support, and the outer layer, when it exists, has a thickness of 1...2 mm and is in intimate contact with the active layer. According to the invention, the process for preparing the recipient consists in mixing 1.5...9.0 parts by weight of low density polyethylene with 0.3% by weight biocide powder which is previously homogenized for 20 minutes, the mixture is introduced into a die in a rotary movement, which is maintained at temperature for 25 min, for depositing the polyethylene layer on the walls, is cooled slowly under ventilation, the rotary movement is stopped and the resulting mono-layer recipient is extracted. According to the invention, the process for making the bi-layered recipient consists in that 7.5 parts by weight of low density polyethylene needed for forming an outer layer, are introduced into a heated die which is a rotating and maintained in the oven for 10 min, afterwards in the die there is introduced a mixture of low density polyethylene, with biocide powder, it is maintained for further 5 min, at temperature, for forming the inner layer, it is cooled slowly under ventilation, then the rotary movement is stopped and the resulting bi-layered recipient is extracted.

Description

The invention relates to a container for storing a liquid intended for food consumption, monolayer or bistro, and to a process for making it by rotational formation.

It is known the manufacture of containers made of thermoplastic materials, generally of polyethylene and ethylene copolymers, which can be done by extrusion-blowing and rotational formation. Compared to the extrusion-blowing process, the rotational formation presents some major advantages: it allows the formation of large items, at a competitive price; the molds have a relatively low cost; the products have no residual mechanical stress.

In rotational formation, the raw material in powder form is introduced into a closed mold, which rotates simultaneously along two axes. The mold is inserted into an oven and heated so that the material melts and adheres to the walls of the mold. After the material has melted, the mold is removed from the oven, cooled until the part returns to solid state and is then extracted from the mold. Both the formation stage in the oven and the cooling stage are executed with the mold in rotation motion after the two axes, to fix the material to the walls of the mold.

The main disadvantage of the containers made of thermoplastic materials is that the water or other liquids cannot be stored without circulation for more than 20 days, due to the development of bacteria, algae and fungi. The solutions known so far generally use chlorine-containing organic compounds, which, however, have a high migration rate due to the small molecule, are temperature sensitive and present an increased risk to the environment.

The technical problem, which is solved by the invention, is the manufacture of a container of thermoplastic materials, monolayer or bistrate, using an inorganic bactericidal (biocide) agent, composed of a mixture of titanium dioxide as an inert material and silver chloride as the active agent.

The container for storing a liquid for food consumption according to the invention, which is made up of an active layer of polyethylene having silver ions, which layer can be protected by an outer layer made only of polyethylene, consists in that the layer active has a thickness of 0.05 ... 1 mm and a content of 0.005 ... 0.3% by weight of powder containing Ag ⁺ ions with biocidal activity coming from AgCI deposited on an inert TiO _{2 support} , and the outer layer, when it exists, has a thickness of 1 ... 2 mm and is in close contact with the active layer.

The powder with biocidal activity consists of an inert support of titanium dioxide and silver chloride in weight ratio titanium dioxide: silver chloride of 8: 2.

The process of making a container for storing a liquid for food consumption according to the invention consists in mixing 1.5 to 9.0 parts by weight of low density polyethylene with 0.3% by weight of biocidal powder homogenized in prior to 20 minutes, the mixture is introduced into a mold that is maintained at a temperature of 230 ° C, for 25 minutes, the mold is rotating around the two axes of rotation, primary and secondary, with a speed of rotation of 8.0 rot / min and 2.1 rot / min respectively, keep the mold in the oven for 5 minutes, to deposit the polyethylene layer on the walls, cool slowly for 40 minutes under ventilation, stops the rotation movement and extracts the resulting monolayer container.

The process of making a container for storing a liquid for food consumption according to the invention, bistrate, consists in the fact that 7.5 parts by weight of low density polyethylene required to form an outer layer are introduced into a mold heated to a temperature of 230 'C, a rotating mold, is kept in the oven for 10 minutes, after which a mixture of 1.5 parts by weight of low density polyethylene with 0.1% by weight homogenized biocidal powder is introduced into the mold. for 20 minutes, keep for another 5 minutes at 230'C, for the formation of the inner layer, cool slowly under ventilation for 20 minutes, after which the rotation movement is stopped and the resulting bistable container is extracted.

RO 119784 Β1

Compared to the use of organic biocides, the use of this biocidal mixture container in 1 active contact layer has the following advantages:

- can be used with any of the raw materials used in rotational formation, linear polyethylene3, low density polyethylene, high density polyethylene, polypropylene etc;

- high activity on a wide spectrum of microorganisms, such as bacteria, algae, 5 fungi;

- very low level of toxicity; 7

- it does not raise health problems being non-irritating and non-allergic;

- minimal impact on the environment; 9

- thermally stable up to 450'C and in a wide pH range;

- the equilibrium concentration is 3 parts per million in water and the silver ions are released 11 as they are consumed, thus ensuring a long duration of activity;

- minimal impact on the characteristics of the basic material; 13

- excellent performance in thin layer.

Laboratory studies using the thin-layer method on bacterial cultures (Staphylo-15 coccus aureus and Escherichia Coli) show a 99.6% reduction for Staphylococcus aureus and 95.2% for Escherichia Coli, 24 hours after application.17

The mixture of titanium dioxide as an inert material and silver chloride as the active agent, in a ratio of 8: 2 by weight ratio, must be very well homogenized and ground very finely, the residue on the 45 pm sieve being a maximum of 0 , 02%.

Containers using this biocide are made by introducing it into the raw material as a powder, in a concentration ranging from 0.005% by mass for a layer with a thickness of 50 µm and 0.3% for a layer with a thickness of 3 mm, very good homogenization 23 and the actual production of the product. Due to the fact that the activity of the biocide is manifested at the interface between the wall and the liquid, it is more economical and efficient to use it in products 25 with double layer walls, the biocide being introduced only in the inner layer which can have a thickness of about 0.5. .1 mm. 27

Following are two examples of low density linear polyethylene, by rotational formation, of a container according to the invention, for drinking water, with a capacity of 5001, of cylindrical shape, with a wall thickness of about 3 mm. The first example is with monolayer wall and the second with double layer wall. 31

Example 1. Weigh 9 kg of low density linear polyethylene (LLDPE) and 27 g of biocide (titanium dioxide mixture: silver chloride at 8: 2 mass) and mix 33 very well in a dry powder mixer.

Insert the mixture into the mold and close the mold.35

Set the oven temperature to 230'C, allow to thermostat and insert the mold into the oven. The mold is continuously rotating, the speed on the primary axis being 837 rpm and on the secondary axis 2.1 rpm.

After 10 minutes, about 3 minutes for every 1 mm wall thickness, when all the material 39 is melted, remove the mold from the oven.

After removing from the oven, the mold is cooled slowly, about 20 minutes, using a fan of 41 capacity. Throughout the cooling phase, the mold is rotating.43

After cooling, when the material has returned to its solid state, the rotation movement is stopped, the mold is opened and the product is removed.

The product is cleaned from the debris found on the molding plans of the mold.

The container is ready for use in operation.47

RO 119784 Β1

Example 2. Weigh two portions of low density linear polyethylene (LLDPE), one 7.5 kg which will form the outer layer and one 1.5 kg which will form the inner layer. Separately, weigh 1.5 g biocide (titanium dioxide mixture: silver chloride in 8: 2 mass ratio). The 1.5 kg polyethylene is well homogenized with the 1.5 g biocide.

Put the 7.5 kg polyethylene into the mold and close the mold.

Set the oven temperature to 230'C, allow to thermostat and insert the mold into the oven. The mold is continuously rotating, the speed on the primary axis being 8 rot / min, and on the secondary axis 2.1 rot / min.

After 10 minutes (about 3 minutes for every 1 mm wall thickness), when all the material that will form the outer layer is melted, remove the mold from the oven.

Remove the vent plug, insert the polyethylene-biocidal mixture into the mold, re-insert the vent plug and insert the mold into the oven.

Leave the mold in the oven for about 5 minutes so that all the material that forms the inner layer melts.

Remove the mold from the oven and chill slowly for about 20 minutes, using a suitable capacity fan. Throughout the cooling phase, the mold is rotating.

After cooling, when the material has returned to solid state, the rotation movement stops, the mold is opened and the product is removed.

The product is cleaned from the debris found on the molding plans of the mold.

The container is ready for use in operation.

For the inner layer, the same material as the outer layer may be used, or preferably a material with elastic characteristics, such as a high-α-olefin polyethylene, which improves shock resistance.

Claims (5)

claims 1. Container for storing a liquid intended for food consumption, which consists of an active layer of polyethylene having silver ions, which layer can be protected by an outer layer made only of polyethylene, characterized in that the active layer It has a thickness of 0.05 ... 1 mm and has a content of 0.005 ... 0.3% by weight of powder containing Ag ⁺ ions with biocidal activity, coming from AgCI, deposited on an inert TiO _{2 support.} , and the outer layer, when it exists, has a thickness of 1 ... 2 mm and is in close contact with the active layer. 2. Container according to claim 1, characterized in that the powder with biocidal activity consists of an inert support of titanium dioxide and silver chloride in weight ratio of titanium dioxide: silver chloride of 8: 2. Process for making a monolayer container, defined in claims 1 and 2, characterized in that 1.5 to 9.0 parts by weight of low density polyethylene with 0.3% by weight of biocidal activity powder are mixed. , homogenized beforehand for 20 minutes, the mixture is introduced into a mold which is maintained at a temperature of 230'C, for 25 minutes, which is rotating around the two axes of rotation, primary and secondary, with a rotation speed of 8.0 rot / min and 2.1 rot / min respectively, keep the mold in the oven for 5 minutes, to deposit the polyethylene layer on the walls, cool slowly for 40 minutes under ventilation , stop the rotation movement and extract the resulting monolayer container. 4. Process for making a bistable container, as defined in claims 1 and 2, characterized in that 7.5 parts by weight of low density polyethylene required to form an outer layer are introduced into a mold heated to a temperature of 230'C. , in motion by RO 119784 Β1 rotation, kept in the oven for 10 minutes, after which a mixture of 1 1.5 parts by weight of low density polyethylene with 0.1% by weight powder with biocidal activity, homogenized previously was introduced into the mold. for 20 minutes, keep for another 5 minutes at 230'C, 3 for the formation of the inner layer, cool slowly under ventilation for 20 minutes, after which the rotation movement is stopped and the resulting bistable container is extracted. 5 5. Process according to claims 3 and 4, characterized in that the powder with biocidal activity is constituted by an inert support of titanium dioxide on which silver chloride powder is deposited in weight ratio of titanium dioxide: chloride of chloride. 8: 2 silver.