NL9401891A - Packaging which absorbs UV radiation - Google Patents

Abstract

The invention relates to packaging for food based on soda- lime glass which is green in colour, absorbs ultraviolet radiation and transmits visible light, containing at least 2.5 wt% of iron, calculated as Fe2O3 on the basis of the weight of the glass, the ratio <IMAGE> in the glass not exceeding 0.25.

Description

Title: UV radiation absorbing packaging.

The invention relates to a packaging for foodstuffs that are sensitive to UV radiation. More particularly, the invention relates to a package consisting of UV absorbing green glass, for example a bottle consisting of UV absorbing, visible light, largely transparent green glass, for packaging food and drinks.

As is known, ultraviolet radiation, more particularly radiation with a wavelength less than about 400 nm, has a negative influence on the smell and taste of foods and drinks, such as beer. This negative influence is attributed to the chemical conversion of components under the influence of UV radiation.

It has long been known that it is possible to reduce UV radiation by using glass with a number of additives, usually metal compounds. Until recently, UV radiation absorbing green glass, which is the subject of the present invention, was mainly obtained by incorporating chromium compounds into the glass. EP-A 261.725 describes the manufacture of green UV radiation absorbing soda-lime glass with an amount of chromium compounds, which may have been partially replaced by nickel compounds. The use of mainly chromium compounds, and to a lesser extent nickel compounds, is increasingly perceived as less desirable, both from the point of view of costs and from the point of view of environmental effects of the metal compounds.

It is already known from the literature that green colored glass with an absorbing capacity for IR and UV radiation can be obtained by incorporating iron compounds in glass. This usually concerns the manufacture of glass that is used for windows, for example heat and light-resistant car windows. In general, this involves a small reduction in the transmission of the radiation, due to the absorption of a small amount of iron, usually in combination with a number of other additives.

The amount of iron compounds in such glass compositions is generally less than 2 more especially less than 1% by weight of the glass composition.

The transmission of UV radiation with such glass compositions is still high, because otherwise the transmission of the visible light is inhibited too much. For this reason, the transmission at 380 and 400 nm is still at a level that makes the glass composition unsuitable for use as packaging glass for food and drinks sensitive to UV radiation.

On the other hand, the problem arises that the visible light transmission must be at least partially maintained because the consumer / user must be able to see the contents of the package. Also, the desire to obtain a particular color may at least partially contradict the objective of UV radiation absorption.

It is an object of the invention to provide a packaging for food and / or drinks that are sensitive to UV radiation, which packaging is based on chromium-free and preferably also nickel-free green soda-lime glass. More specifically, it is an object of the invention to provide a package whose transmission of radiation with a wavelength of <400 nm and more particularly also of 380 nm, with a glass thickness of 2 mm, is nil or negligibly small. , while maintaining at least part of the visible light transmission.

The invention is based on the surprising insight that such objectives can be achieved by using a relatively large amount of iron in soda-lime glass. The invention therefore relates to a packaging for foodstuffs based on green-colored, ultraviolet radiation-absorbing and visible light-transmitting soda-lime glass, at least consisting of 2.5% by weight of iron, calculated as Fe2Ü3 relative to the weight of the glass.

Surprisingly, it has been found that such a packaging meets the requirements that can be imposed on the UV absorption at 380 and 400 nm, while still obtaining a good green color, which can furthermore be adjusted by choosing the conditions for the melting, as well as by choosing the other components of the glass blend.

Also the degree of absorption at said wavelengths can be adjusted by these choices, taking into account that the total amount of iron and the ratio Fe (II) to Fe (III) in the final glass are of great importance for the obtaining the correct properties with regard to color and UV absorption, respectively transmission of visible light. Preferably the ratio FE (II)

Fe (ii) + Fe (lfi) in the glass not greater than 0.25.

This ratio between divalent and trivalent iron is of great importance for obtaining the correct properties of the glass. This ratio is expressed as _ ._T. — 1 -, τττν ie the amount of divalent iron in relation to the total iron. Preferably, the amount of divalent iron is as small as possible, i.e. less than 0.2. In practice, values smaller than 0.05 are difficult to realize. The total amount of iron should not be less than about 2.5% by weight calculated as Fe 2 O 3, otherwise its effect will not be sufficiently achieved. On the other hand, no more than about 15% by weight calculated as Fe2 <!> 3 need be used. Larger quantities cause problems with the required transmission for visible light.

In the following table the transmission (T) at 380 and 400 nm is given as a function of the iron content, measured on soda-lime glass with a thickness of 2 ram.

It is noted that in J. of the Society of Glass Technology, 22, (1938), p. 372-389 a theoretical consideration has been given on the balance between Fe (II) and Fe (III). In this article, amounts of 0.002 to 12.50 wt% iron, calculated as Fe 2 O 3, in soda-lime glass have been investigated. This publication gives no indication of the properties of the glass with respect to UV absorption or with regard to the use of such glass for packaging purposes.

On the one hand, the packaging according to the invention is characterized in that the transmission for radiation of 380 nm nm at a glass thickness of 2 mm is <5%, more in particular <1%, and at 400 nm <20% more in particular < 5% and most preferably <1%, which in practice means that the package absorbs the UV radiation completely or almost completely, while on the other hand the visible light is largely transmitted and the color of the glass is green. The latter means that the dominant wavelength of the glass is slightly in the range of 500 to 565 nm. Of course it is also possible to define the color using the CIE-Lab system. Assuming a measurement of transparent colored glass with a thickness of 2 mm, against a white background with L * = 98.89, a * = -0.06 and b * = 0.02, with D65 light at an observation angle of 2 °, with a BYK-Gardner spectrometer, type Spectrogard Automatch Color System TCM 8800, under standard CIE lab conditions the color can be defined as follows: L * - 0 - 80, a * - 0 - -35 and b * = - 10 - +55.

The packaging according to the invention is based on soda-lime glass, which has the advantage that its costs remain low. This can be particularly important for glass that is used only once and then recycled again. The components of such soda-lime glass compositions are known to the person skilled in the art.

According to the invention, substantially no chromium, vanadium, nickel and cobalt are used; as already indicated, this is important from both a cost and environmental point of view. Especially in the event that the packaging must be suitable for single use, the absence of such metals is of great importance. Also, the glass should not contain arsenic and tin, as these substances are undesirable in the glass because of their environmental effects. In this regard, it is noted that, in connection with the present invention, although reference is made to the use of metals, these metals will exist in the final glass in the form of compounds thereof, mainly oxides.

Generally, it is preferred that the glass is comprised of 2.5-10 wt% iron calculated as Fe 2 O 3 50-85 wt% S1O2 5-25 wt% alkali metal oxide 5-25 wt% earth alkali metal oxide 0 -5 wt. % alumina 0-5 wt% spores

The amount of iron is preferably between 2.75 and 8% by weight. As trace components, various additives can be used which influence the properties (color, ratio Fe (II) / Fe (III), melting properties and the like). Examples of such components are manganese and titanium.

The package is manufactured in the usual manner for manufacturing glass, by melting the components in an oven, under conditions such that the desired degree of oxidation of the iron is achieved. In the present invention, the degree of air supply during melting proves to be important. By controlling this, the ratio of divalent and trivalent iron can be influenced.

The packaging is suitable for contact with food and drinks, such as soft drinks, alcoholic drinks and fruit juices. More particularly, the packaging is suitable as a beer bottle, since beer has the property of deteriorating strongly in quality when exposed to UV radiation.

The invention is illustrated by the following examples.

EXAMPLES

Soda-lime glass was made by air melting at a temperature of 1450 ° C. The composition of the batch was in parts by weight:

This leads to the following basic glass composition:

In the following table, the transmission (T) at 380, 400, 500 and 600 nm, as well as the color, are given as a function of the amount of iron.

Claims (9)

1. Food packaging based on green colored, ultraviolet ray absorbing and visible translucent soda-lime glass, at the very least, consisting of 2.5 wt.% Iron, calculated as Fe203 relative to the weight of the glass. Packaging according to claim 1, wherein the FE (Xi) ratio + pe (iii) in the 9seal does not exceed 0.25, preferably does not exceed 0.15. Packaging according to claim 1 or 2, characterized in that the transmission of the glass for radiation of 380 nm at a thickness of 2 mm is <5%, preferably <1%. Packaging according to claims 1-3, characterized in that the transmission for radiation of 400 nm at a thickness of 2 mm is <20%, preferably <5%. Packaging according to claims 1 to 4, characterized in that the iron content, calculated as Fe 2 O 3, is greater than 2.75% by weight, but not more than 8% by weight. Packaging according to claims 1-5, characterized in that the glass contains substantially no chromium, nickel, cobalt, vanadium, arsenic and tin. Packaging according to claims 1-6, characterized in that the glass consists of 2.5-10 wt.% Iron calculated as Fe223 50-85 wt.% SiO2 5-25 wt.% Alkali metal oxide 5-25 wt.% Alkaline earth metal oxide 0-5 wt. % alumina 0-5 wt% spores The green glass manufacturing method according to claims 1-7, wherein the amount of Fe (III) is adjusted by adjusting the furnace conditions or by adding equilibrium-moving ions. 9. Use of at least 2.5 wt.% Iron, calculated as Fe203 relative to the weight of the glass, in FE (JX) soda-lime glass with a ratio ρβ (χχ) + Fe (Ill) in the glass. greater than 0.25, for inhibiting the transmission of UV radiation with a wavelength of 380 and / or 400 nm, with a glass thickness of 2 mm