WO2008080577A1 - Plastic container for beverages containing carbon dioxide - Google Patents

Abstract

The invention relates to a plastic container for beverages containing carbon dioxide, wherein the plastic comprises at least one additional material and/or is a plastic which undergoes at least one additional treatment. Owing to the at least one additional material or the additional treatment, the plastic is more hydrophilic, at least on the surface thereof which faces the beverage containing carbon dioxide (the surface of the plastic which contacts the beverage containing carbon dioxide), than a plastic without the at least one additional material and/or the at least one additional treatment.

Description

 Pi Patents

Limited liability company (GmbH) Development and utilization

Rodheimer Straße 6 35435 Wettenberg / OT Krofdorf-Gleiberg

Plastic container for beverages containing carbon dioxide

description

The invention relates to a plastic container, in particular a plastic bottle for carbon dioxide-containing beverages.

The term "carbon dioxide-containing beverage" and "non-carbonated" beverage is always used below, since solutions of carbon dioxide in water, of which beverages are predominantly composed, contain substantially dissolved carbon dioxide molecules and less than one Percent of it actually be converted to carbonic acid.

State of the art:

According to the state of the art, carbon dioxide-containing beverages are to a considerable extent bottled and stored. This type of packaging of a drink serves many purposes. First bottling, then storage and shelf life. In addition, claims of transport and sale to the end customer must be met.

The plastic bottle has gained increasing market share in this market segment in recent years, as its advantages over the glass bottle, such as lower weight and resistance to breakage, outweigh the packaging of most beverages.

These known plastic bottles are made according to the prior art for the most part from the plastic polyethylene terephthalate, hereinafter called PET. In addition to all the advantages of these plastic bottles compared to glass bottles, the plastic bottles have the disadvantage that their walls are more permeable to gases than the walls of comparable glass beverage bottles.

For almost all drinks, this so-called gas-tightness of the beverage packaging is of utmost importance for the shelf life and also the taste of the beverage.

The present invention is concerned with the improvement of plastic bottles for carbonated beverage. In that regard, the state of the art lent importance to the gas-tightness of the plastic bottles for carbon dioxide from the beverage, which will be discussed below.

This gas-tightness is first determined according to the prior art by the nature of the plastic itself, which is used for the production of the beverage bottle. Considering also other essential aspects PET is used here today mostly.

The further influence on the gas-tightness of such a plastic bottle has the material thickness of the bottle wall. Due to the raw material price of the plastic but also by the weight of the finished beverage bottle the improvement of the gas-tightness by increasing the material thickness of the bottle wall economic and logistical limits.

For the above reason, further methods for improving gas tightness have been developed. According to the prior art, a thin glass coating is applied to the inside of such a plastic bottle, that is to say the potential contact surface of the plastic with the carbon dioxide-containing beverage. This method is very effective, but relatively expensive and technically feasible only with considerable effort. Furthermore, this type of improvement of the gas-tightness is contrary to the material recycling and causes difficulties in this case.

Furthermore, so-called nano-particles have been added to the plastic in order to achieve a better gas-tightness of the plastic. The results obtained are controversial. Again, this procedure is recommended by professionals evaluated in his cost-benefit ratio for not very practical.

The prior art (U.S. Patent No. 4,421,804) includes a carbonated beverage bottle made of plastic, to which a dibutyl sebacate is added, in a concentration of up to 0.5% to reduce the gas pressure in the headspace of the bottle ,

Object of the invention:

The technical problem underlying the invention is to provide a plastic container for carbon dioxide-containing beverages, in which the loss of carbon dioxide is reduced from the bottled in the plastic container beverage.

This technical problem is solved by a plastic container with the features of claim 1.

It is important for the invention that the task is to better preserve the carbon dioxide in the beverage by the properties of the plastic. This is not necessarily synonymous with a better gas tightness of the plastic. This is just the assumption from which each state of the art goes out so far.

The invention ignores this hitherto false assumption and shows a completely new way of counteracting the loss of carbon dioxide from the beverage. This is done by means of a different property of the plastic than the gas-tightness.

Invention: The above finding is already a first part of the invention and is supplemented by the subsequent designation of suitable means to counteract the loss of carbon dioxide from the beverage.

Substances have a specific surface energy, which is given in millinewtons per meter. This specific surface energy is based on the so-called van der Waals forces, which include all intermolecular attractive forces between atoms and / or molecules.

The Van der Waals forces consist of three groups of attractions.

The dipole-dipole forces occur only in molecules, not in atoms, which is due to their formation. They are generated in the molecules by the permanent spatial displacement of electrons on predominantly one side of the molecule. This spatial shift itself is generated by the attraction of at least one atomic nucleus of the molecule to the electrons involved. Outwardly, the molecule shows a positive and negative force of attraction, so-called poles, which are permanently present and in each case spatially opposite. This attraction acts between polar molecules.

The hydrogen bonds are also dipole-dipole forces, but are called hydrogen bonds, because hydrogen is included in the dipole-dipole molecule and, as a result, the attraction energy acting on other dipole-dipole molecules is relatively strong. The London forces, also called dispersion forces, arise from the unequal distribution of the electron cloud around the atomic nucleus. The atom is thereby in positive frequency on one spatial side positive and then negative, on the opposite side correspondingly reversed. The sequence is so fast that during a measurement the atom appears neutral to the outside. Such an atom is therefore called non-polar, but this does not mean that there are no attractions, because if a neighboring atom has the same properties, there is considerable mutual attraction despite the rapid pole change.

The described attractive forces cause the binding in a substance by the attraction of the atoms and / or molecules among themselves. In this case, there are attractions between polar substances and attractive forces between non-polar substances. Non-polar and polar substances do not attract each other. However, a large number of molecular compounds have quite polar and nonpolar portions at the same time. Both attractions also act as specific surface energy on the surface of each substance. The size of the forces is given in millinewtons per meter (mNm ^"1 ).

The invention generally relates to plastic containers.

However, the following explanations are only made for beverage bottles. However, they equally refer to all KunstStoffbehälter in general.

For the production of beverage bottles, the plastic PET is usually used. This plastic has a special -specific surface energy of about 43.0 itiNm ^-1. As a result, the inner beverage bottle surface, which forms the contact surface with the carbon dioxide-containing beverage, according to the prior art, this value of specific energy.

According to the invention, this specific surface energy of the plastic bottle, at least at its contact surface with the carbon dioxide-containing beverage, is increased to more than 55.0 mNm ^-1 . This is achieved by making this contact surface highly polar and thus hydrophilic by suitable measures.

The use of already known methods to make a plastic on its surface highly hydrophilic, here serves a completely new inventive purpose and is used specifically for the improvement of plastic bottles, which has not been the case.

The significantly higher specific surface energy of the contact surface of the plastic bottle acts, as will be explained below, in many ways successfully against the loss of carbon dioxide from the beverage. The carbon dioxide remains much better in the beverage and therefore also occurs less through the wall of the plastic bottle to the outside. The shelf life of the beverage is thereby significantly extended.

The water content of the beverage is attracted by the higher specific surface energy of the contact surface of the plastic bottle, since water has a strong dipole content. As a result, the water molecules store more and closer to this contact surface of the plastic bottle and form an additional barrier for the carbon dioxide molecules. The carbon dioxide molecules are not attracted to the polar surface of the plastic of the beverage bottle because carbon dioxide is non-polar.

Furthermore, the attraction of the contact surface of the plastic bottle on the water content of the drink enhances the attraction of the water molecules with each other. Since the carbon dioxide molecules are located in the spaces between the water molecules, they are better retained there. The non-polar carbon dioxide molecule is then trapped in the surrounding water in a polar field.

To get out of such a field, the carbon dioxide known to help a so-called germ in the form of an additional surface. These are normally roughness of the plastic surface of the plastic bottle on the inner wall in the normal case. Due to the higher concentration of water molecules on the inner wall of the plastic bottle, carbon dioxide is denied access to these germs.

The plastic container for carbon dioxide-containing beverages according to the invention is characterized in that the plastic has at least one additive and / or is formed as a plastic subjected to at least one additional treatment, wherein the plastic by at least one additive or at least one additional treatment at least its surface facing the carbon dioxide-containing beverage (contact surface of the plastic to the carbon dioxide-containing beverage) is made more hydrophilic, as a plastic without the at least one additive and / or the at least one additional treatment. This leaves the carbon dioxide in a lot greater extent in the beverage than in the prior art plastic containers.

According to a preferred embodiment of the invention, the contact surface of the plastic container with the carbon dioxide-containing beverage has a specific surface energy of more than 55 mNm ^-1 (millinewtons per meter).

According to a further advantageous embodiment of the invention, the contact surface of the plastic container to the carbon dioxide-containing beverage has a higher specific surface energy than water, ie more than 72.8 mNm ^"1 on.

Advantageously, the at least one additive which produces the higher hydrophilicity of the plastic, at least one surfactant. This is an inexpensive additive that can be used to achieve the required properties.

According to a further embodiment of the invention, the at least one additive which produces the higher hydrophilicity of the plastic is a synthetic surfactant, ie a detergent. This surfactant is particularly suitable because it is inexpensive.

Advantageously, the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide-containing beverage compared to the normal value of this plastic by adding a fatty acid to the plastic.

Advantageously, the specific surface energy of the contact surface of the plastic container to the carbon dioxide-containing beverage compared to the normal value of this Kunst- Substance increased by adding a fatty acid partial ester mixture to the plastic.

According to a further advantageous embodiment of the invention, the specific surface energy of the contact surface of the plastic container to the carbon dioxide beverage over the normal value of this plastic by adding a fatty acid partial ester mixture of Oleo Chemicals (company name) with the name Loxiol A4 (brand name) is increased to the plastic.

Advantageously, the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide-containing beverage compared to the normal value of this plastic by adding Dibutylsebazat to the plastic.

Advantageously, the specific surface energy of the contact surface of the plastic container to the carbon dioxide-containing beverage compared to the normal value of this plastic by adding an anionic / nonionic surfactant Atmer 1440 (product of ICI (company name)) to the plastic increased. This product has proven to be inexpensive and suitable.

Advantageously, the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide-containing beverage compared to the normal value of this plastic by the addition of an additive in an amount of 0.5 to 5 percent by volume.

According to a further advantageous embodiment of the invention, the specific surface energy of the contact surface of the plastic container to the Kohlendioxydhal- term beverage increased compared to the normal value of this plastic by painting the contact surface.

Advantageously, the specific surface energy of the contact surface of the plastic container to the carbon dioxide-containing beverage compared to the normal value of this plastic is increased by a plasma treatment of the plastic.

Advantageously, the specific surface energy of the contact surface of the plastic container to the carbon dioxide-containing beverage compared to the normal value of this plastic is increased by subjecting the contact surface of a corona treatment.

Advantageously, the specific surface energy of the contact surface of the plastic container to the carbon dioxide-containing beverage compared to the normal value of this plastic is increased by this plastic is grafted even before the preparation of the container, another plastic, which is highly polar and the specific surface energy is increased.

Advantageously, the contact surface of the plastic container with the carbon dioxide-containing beverage is formed as a contact surface drawing through its specific surface energy the water applied to it in a flat shape.

Advantageously, the contact surface of the plastic container with the carbon dioxide-containing beverage is a contact surface that flattens through its specific surface energy and has a water droplet applied to it. forms such that the remaining wetting angle is less than 46 degrees.

Advantageously, the contact surface of the plastic container to the carbon dioxide-containing beverage is formed by their specific surface energy as a contact surface in which forms a liquid film using the water in the beverage on its surface, in which the proportion of carbon dioxide is lower than the proportion of Carbon dioxide in the rest of the drink.

Advantageously, the contact surface of the plastic container with the carbon dioxide-containing beverage is formed as a contact surface covering its own surface by the formed liquid film, and thus the quantity of its own actual contact surface with the carbon dioxide in the beverage is considerably reduced.

The carbon dioxide of the carbon dioxide-containing beverage, which is arranged in the plastic container, migrates from the beverage with closed plastic container much less through the bottle walls to the outside than in the prior art PET bottles.

Advantageously, the contact surface of the plastic container with the carbon dioxide-containing beverage is formed as a contact surface acting on the van der Waals forces of the beverage liquid by its specific surface energy and reinforcing its binding effect.

According to a particularly preferred embodiment of the invention, the plastic container is designed as a closable bottle. This is the most common form of a container for a drink. EXAMPLES

There are methods and / or methods are used, which are known in other areas of the plastics industry. The various known methods serve to increase the specific surface energy of plastic films but not plastic bottles. In the prior art, the increase of the specific surface energy in plastic films also serves other purposes than in the invention.

Increasing the specific surface energy of plastic films makes it easier to print on them.

Increasing the specific surface energy of plastic films makes it easier to laminate them.

Another known application is obtained when such plastic films are used as top films of so-called MAP (Modification Atmosphere Packaging) packs. Then, these hydrophilic properties of the plastic films serve to cause condensation, which may be deposited on the underside of the plastic film, to become a water film, that is to prevent droplet formation of the condensed water, since this greatly enhances the view of the product packaged in the MAP package would affect.

The specific surface energy of such surfaces can be measured by the so-called static contact angle measurement by applying a drop of a test liquid of known surface tension to the surface. About the creation of a tangent to the Drops at the point of contact, the angle formed between the tangent and the base can be measured and used to calculate the specific surface energy.

Representing all other processes for the production of particularly hydrophilic plastic surfaces, ie plastic surfaces with high specific surface energy, one of these processes is described below, which is suitable for the invention:

The plastic granulate, here polyethylene terephthalate (PET), is mixed to produce the plastic bottle before the production of the plastic bottle, a proportion of the agent Loxiol A4 in a concentration of 2 percent as an additive. Such a substance has a hydrophilic portion and a hydrophobic portion which is lipophilic. In other words, it is a fatty acid partial ester mixture having surfactant properties with high oil solubility of the nonpolar end of the molecule.

During the manufacturing process of the plastic bottle, the plastic is heated above its melting point. Here and afterwards, the lipophilic part of the additive seeks to remain in the PET because it likes to associate with the PET. The hydrophilic part of the additive strives away from the PET and thus comes to the surface of the plastic bottle. Thus, there is an orientation and / or orientation of the additive molecules. As a result, the contact surface of the plastic bottle with the carbon dioxide-containing beverage is strongly hydrophilic as intended.

In practice, this causes much less carbon dioxide to escape from the beverage in the plastic bottle. For a PET plastic bottle optimally manufactured in this respect, the specific surface energy is then at least 60 millinewtons per meter. For a similar PET plastic PET bottle that has not been modified in that direction, the surface specific energy value is comparatively about 43 millinewtons per meter.

Further advantages of the invention:

Based on its mode of action, the invention contains further advantages:

After carbon dioxide-containing beverages are filled in plastic bottles and these plastic bottles are then sealed tight, an overpressure is created in the plastic bottles. This is due to the fact that carbon dioxide exits in gaseous form from the beverage, thereby increasing the gas density in the headspace of the plastic bottle. The gas pressure increases until a so-called equilibrium is reached. The equilibrium is reached when at the same time as many gas molecules escape from the beverage into the headspace as at the same time gas molecules return to the beverage. The gas pressure then no longer increases and no longer decreases.

As is known, this process is also temperature-dependent. At low temperature, this equilibrium sets in at a lower gas pressure. At higher temperatures, a higher gas pressure is created in the headspace of the plastic bottle until equilibrium is reached. For safety reasons, it is desirable with carbon dioxide-containing beverages to achieve this equilibrium state with the lowest possible gas pressure in the head space of the plastic bottle.

In a plastic bottle according to the invention acts on the water content of the drink, the inner polar surface of the plastic bottle in such a way that the binding forces between the water molecules are increased. As a result, the carbon dioxide molecules, which are dissolved in the interstices in the water, tethered. The pressure increase until equilibrium in the head space of a plastic bottle according to the invention is therefore only 70% or less than the pressure increase in the head space of a comparable plastic bottle which is not equipped according to the invention.

As already described, due to the hydrophilic inner surface of the plastic bottle, more and more water molecules from the beverage are deposited on the inner surface of the plastic bottle. As a result, the carbon dioxide molecules are denied access to germs to a considerable extent. These germs in the form of the roughness of the plastic surface are mainly produced by cleaning the plastic bottles, which is necessary in the deposit system. As a result, the average circulation number of a plastic deposit bottle is limited, because too many germs, the leakage of carbon dioxide is too strong. Since the contact of the carbon dioxide is reduced to the inner bottle wall and thus to the germs as described, a higher circulation rate of the plastic bottles according to the invention in the deposit system is possible. The system described above is also advantageous when a plastic bottle has been opened. If the carbon dioxide-containing beverage from an open plastic bottle according to the invention is not immediately consumed, the beverage is not stale as quickly as the same beverage in an opened comparable plastic bottle, which is not equipped according to the invention.

Comparative tests with the prior art bottles (US Pat. No. 4,421,804) have shown that with up to 0.5% addition of the dibutyl sebacate, the passage of carbon dioxide through the wall of the container is even slightly increased compared to a standard container ie without the addition of additives. In that regard, the prior art here in the wrong direction. In contrast, when more than 0.5% of dibutyl sebacate is added, the carbon dioxide permeation decreases. The addition according to the invention from 1% to 2% has proven to be particularly advantageous.

Further features and advantages of the invention will become apparent from the accompanying drawings, in which an embodiment of a beverage bottle according to the invention is shown only by way of example. The single drawing shows a beverage bottle.

The figure shows a beverage bottle 1, which consists of a base body 2. The main body 2 has a wall 3. The bottle 1 has a bottom 4 and a bottleneck 5. The bottle neck 5 opens into an opening 6 for filling the bottle 1 and for pouring the carbon dioxide-containing liquid from the bottle 1. The opening 6 can with a screw (not shown) close be closed. For closing a screw thread 7 is provided.

The entire bottle 1 consists of a plastic in which a contact surface 8 to a carbon dioxide-containing beverage (not shown) has a higher specific surface energy than water.

reference numerals

1 bottle

2 main body

3 wall

4 floor

5 bottleneck

6 opening

7 eyesight thread

8 contact surface

Claims

claims:

1. plastic container for carbon dioxide-containing beverages, characterized in that the plastic comprises at least one additive and / or is formed as a at least one additional treatment plastic, wherein the plastic by the at least one additive or at least one additional treatment at least at its carbon dioxide beverage beverage facing surface (contact surface of the plastic to the carbon dioxide-containing beverage), is formed hydrophilic, as a plastic without the at least one additive and / or the at least one additional treatment.

2. Plastic container according to claim 1, characterized in that the contact surface of the plastic container to the carbon dioxide-containing beverage has a specific surface energy of more than 55 mNm ^'1 (millinewtons per meter).

3. Plastic container according to claim 1, characterized in that the contact surface of the plastic container to the carbon dioxide-containing beverage has a higher specific surface energy than water, that is more than 72.8 mNm ^"1 .

4. Plastic container according to one of the preceding claims, characterized in that the at least one additive which produces the higher hydrophilicity of the plastic, at least one surfactant.

5. Plastic container according to one of the preceding claims, characterized in that the at least one additive which produces the higher hydrophilicity of the plastic, a synthetic surfactant, that is a detergent.

6. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the Kunststoffbehäl- ters is increased to the carbon dioxide-containing beverage over the normal value of this plastic by adding a fatty acid to the plastic.

7. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide-containing beverage compared to the normal value of this plastic by adding a fatty acid partial ester mixture to the plastic.

8. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the Kunststoffbehäl- ters to the carbon dioxide-containing beverage compared to the normal value of this plastic by adding a Fettsäu- repartialestergemisches Oleo Chemicals (company name) with the name Loxiol A4 (trade name ) is increased to the plastic.

9. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the Kunststoffbehäl- ters to the carbon dioxide-containing beverage over the Normal value of this plastic is increased by adding Dibutylse- bazate to the plastic.

10. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the Kunststoffbehäl- ters to the carbon dioxide-containing beverage over the normal value of this plastic by addition of an anionic / nonionic surfactant Atmer 1440 (product of ICI (company name)) to the plastic is increased.

11. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide beverage over the normal value of this plastic by the addition of an additive in an amount of 0.5 to 5 percent by volume.

12. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the Kunststoffbehäl- ters is increased to the carbon dioxide-containing beverage compared to the normal value of this plastic by painting the contact surface.

13. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide beverage over the normal value of this plastic by a plasma treatment of the plastic.

14. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide beverage over the normal value of this plastic by subjecting the contact surface of a corona treatment.

15. Plastic container according to one of the preceding claims, characterized in that the specific surface energy of the contact surface of the plastic container is increased to the carbon dioxide-containing beverage compared to the normal value of this plastic by this plastic is grafted before the manufacture of the container, another plastic, which is highly polar and the specific surface energy is designed to increase.

16. Plastic container according to one of the preceding claims, characterized in that the contact surface of the plastic container is formed to the carbon dioxide-containing beverage as a by their specific surface energy, the water applied to her in a flat shape pulling contact surface.

17. Plastic container according to one of the preceding claims, characterized in that the contact surface of the plastic container is formed to the carbon dioxide-containing beverage as a by their specific surface energy a flat on their applied water droplets contact surface, such that the remaining wetting angle is less than 46 degrees ,

18. Plastic container according to one of the preceding claims, characterized in that the contact surface of the plastic container to the carbon dioxide-containing beverage is formed by their specific surface energy as a contact surface in which forms a liquid film using the water in the beverage on its surface, in which the proportion of carbon dioxide is lower than the proportion of carbon dioxide in the rest of the beverage ,

19. Plastic container according to claim 18, characterized in that the contact surface of the plastic container is formed to the carbon dioxide-containing beverage as a liquid surface formed by the formed their own surface covering contact surface, and thus the quantity of their own actual contact area to the carbon dioxide in the beverage is significantly reduced ,

20. Plastic container according to one of the preceding claims, with a carbon dioxide-containing beverage as the content, characterized in that the carbon dioxide migrated from the beverage with closed plastic container much less through the container walls to the outside.

21. Plastic container according to one of the preceding claims, with a carbon dioxide-containing beverage as the content, characterized in that the contact surface of the plastic container to the carbon dioxide-containing beverage acting as a by their specific surface energy on the van der Waals forces of the beverage liquid and this in their Binding effect reinforcing contact surface is formed.

22. Plastic container according to one of the preceding claims, characterized in that the plastic container is designed as a closable bottle.