PACKAGE FOR PRESERVING RESPIRING PRODUCE AND METHOD

Abstract

A package for preserving respiring produce contained in the package, in particular vegetables, fruit, herbs, spices and/or flowers, and an associated method are provided. The package defines a package volume for containing a portion of the produce and a package atmosphere, and comprises a packaging material, in particular a BOPE or MDOPE-containing polymer film, with a haze of at most 10, preferable at most 5, more preferably at most 3, and most preferably at most 2, provided with one or more perforations enabling gas exchange with the atmosphere surrounding the package to form the package into a Controlled Atmosphere Package (CAP). The package has a package carbon dioxide transmission rate (CO.sub.2TR.sub.pack) and the CO.sub.2TR.sub.pack is at least 1000 ml per 100 gram produce to be packed over 24 hours.

Claims

1. A package for preserving respiring produce contained in the package wherein the package defines a package volume for containing a portion of the respiring produce and a package atmosphere, which package comprises: a packaging material which comprises a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented Poly Ethylene (MDOPE)-containing polymer film with a haze of at most 10, as determined by ASTM D 1003, said polymer film being provided with one or more perforations enabling gas exchange with atmosphere surrounding the package to form the package into a Controlled Atmosphere Package (CAP); wherein: the package has a package carbon dioxide transmission rate (CO.sub.2TR.sub.pack) the one or more perforations provide a perforation carbon dioxide transmission rate (CO.sub.2TR.sub.perf) such that the package carbon dioxide transmission rate (CO.sub.2TR.sub.pack) is a sum of the perforation carbon dioxide transmission rate (CO.sub.2TR.sub.perf) and a material carbon dioxide transmission rate (CO.sub.2TR.sub.mat) of the packaging material (CO.sub.2TR.sub.pack=CO.sub.2TR.sub.perf+CO.sub.2 TR.sub.mat) and the CO.sub.2TR.sub.pack is at least 1000 ml/24 hrs per 100 gram of the respiring produce to be packed.

2. The package according to claim 1, wherein the respiring produce to be packed is selected from the group consisting of freshly cut leafy greens, freshly cut vegetables, fruit, herbs, flowers and prepared salads.

3. The package according to claim 2 wherein the freshly cut leafy greens are selected from the group consisting of lettuce, arugula, spinach, romaine, and combinations hereof.

4. The package according to claim 2, wherein the freshly cut vegetables are selected from the group consisting of green beans, zucchini, carrots, sprouts, leaks, cauliflower, broccoli, and combinations thereof.

5. The package according to claim 2, wherein the fruit is selected from the group consisting of berries, apples, pears, tomatoes, peppers, bananas, stone fruit such as mangos, and combinations thereof.

6. The package according to claim 2 wherein the prepared salads are selected from the group consisting of freshy-cut leafy greens, freshly cut vegetables, fresh fruit and any combination thereof.

7. The package according to claim 1 wherein the thickness of the polymer film is in a range of 5-200 micrometers.

8. The package according to claim 1, wherein the packaging material has a material oxygen transmission rate (O.sub.2TR.sub.pack) and a perforation oxygen transmission rate (O.sub.2TR.sub.perf), and a package oxygen transmission rate (O.sub.2TR.sub.pack) is a sum of the perforation oxygen transmission rate (O.sub.2TR.sub.perf) and the material oxygen transmission rate (O.sub.2TR.sub.mat) of the packaging material (O.sub.2TR.sub.pack=O.sub.2TR.sub.perf+O.sub.2 TR.sub.mat) and a package transmission ratio .sub.pack is .sub.pack=(CO.sub.2TR.sub.perf+CO.sub.2TR.sub.mat)/(O.sub.2TR.sub.perf+O.sub.2TR.sub.mat), and the package transmission ratio .sub.pack=CO.sub.2TR.sub.pack/O.sub.2TR.sub.pack is at least 1.5.

9. The package according to claim 1, wherein the packaging material has an oxygen transmission rate (O.sub.2TR.sub.mat) of at least 2000 ml/(m.sup.2.Math.24 hrs).

10. The package according to claim 1, wherein the packaging material has a carbon dioxide transmission rate (CO.sub.2TR.sub.mat) of at least 15000 ml/(m.sup.2.Math.24 hrs).

11. A package for preserving respiring produce contained in the package according to claim 1 wherein the packaging material comprises a tray and a lidding film sealed to the tray thus closing the package, the lidding film is a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented poly Ethylene (MDOPE)-containing polymer film.

12. A method for manufacturing a package for preserving respiring produce contained in the package, said method comprising steps of: i. providing a closed package defining a package volume for containing in the package volume a portion of the respiring produce, said closed package being made from a packaging material comprising a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented poly Ethylene (MDOPE)-containing polymer film with a haze of at most 10, as determined by ASTM D 1003; and ii. determining a size, and optionally, a number of one or more perforations provided in or to be provided in the packaging material to enable gas exchange between a package atmosphere and an atmosphere surrounding the package to form the package into a Controlled Atmosphere Package (CAP),such that the package has a package carbon dioxide transmission rate (CO.sub.2TR.sub.pack) which is at least 1000 ml/(m.sup.2.24 hrs) per 100 gram produce to be packed.

13. The method according to claim 12, wherein the packaging material has a carbon dioxide transmission rate (CO.sub.2TR) of at least 10000 ml/(m.sup.2.Math.24 hrs).

14. The method according to claim 12, wherein the packaging material has an oxygen transmission rate (O.sub.2TR) of at least 2000 ml/(m.sup.2.Math.24 hrs).

15. The method of manufacturing a package for for preserving respiring produce contained in the package according to claim 12, wherein the packaging material comprises a tray and a lidding film sealed to the tray thus closing the package, and the lidding film is a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented Poly Ethylene (MDOPE)-containing polymer film.

16. The package according to claim 1, wherein the CO.sub.2TR.sub.pack is at least 2500 ml/24 hrs per 100 gram of the respiring produce to be packed.

17. The package according to claim 16, wherein the thickness of the polymer film is in a range of 15-50 micrometers.

18. The package according to claim 17, wherein the package transmission ratio .sub.pack=CO.sub.2TR.sub.pack/O.sub.2 TR.sub.pack is at least 5.

19. The package according to claim 18, wherein the package has an oxygen transmission rate (O.sub.2TR.sub.mat) of at least 5000 ml/(m.sup.2.Math.24 hrs).

20. The package according to claim 19, wherein the package has a carbon dioxide transmission rate (CO.sub.2TR.sub.mat) of at least 30000 ml/(m.sup.2.Math.24 hrs).

Description

DETAILED DESCRIPTION

[0034] The present disclosure provides a package for preserving respiring produce and a method of manufacturing a package for preserving respiring produce contained in the package are provided and specified in the appended claims.

[0035] More specifically, the disclosure is directed to a package for preserving respiring produce contained in the package wherein the package defines a package volume for containing a portion of the produce and a package atmosphere, which comprises: [0036] a packaging material which comprises a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented poly Ethylene (MDOPE)-containing polymer film with a haze of at most 10, preferable at most 5, more preferably at most 3, and most preferably at most 2, as determined by ASTM D 1003 [0037] said polymer film being provided with one or more perforations enabling gas exchange with the atmosphere surrounding the package to form the package into a Controlled Atmosphere Package (CAP); wherein: [0038] the packaging material has a material carbon dioxide transmission rate (CO.sub.2TR.sub.mat) and, [0039] wherein the one or more perforations provide a perforation carbon dioxide transmission rate (CO.sub.2TR.sub.perf) and a perforation oxygen transmission rate (O.sub.2TR.sub.perf), such that the package carbon dioxide transmission rate (CO.sub.2TR.sub.pack) is the sum of the perforation carbon dioxide transmission rate (CO.sub.2TR.sub.perf) and the material carbon dioxide transmission rate (CO.sub.2TR.sub.mat) of the packaging material (CO.sub.2TR.sub.pack=CO.sub.2TR.sub.perf+CO.sub.2TR.sub.mat), and wherein [0040] the CO.sub.2TR.sub.pack is at least 1000 ml/24 hrs per 100 gram produce to be packed, preferably at least 1500 ml/24 hrs, more preferably at least 2000 ml/(24hrs, most preferred at least 2500 ml/24 hrs.

[0041] The packaging material used is a Biaxially Oriented Poly Ethylene (BOPE) or Mono Directed Oriented Poly ethylene (MDOPE)-containing polymer film. When polyethylene film is extruded and stretched in both the machine direction and across machine direction, it is called biaxially oriented polyethylene. When extruded polyethylene film is only stretched on one direction it is called mono directed oriented polyethylene. BOPE film and MDOPE film may be multi-layered. For instance, the BOPE or MDOPE-containing film may also comprise a printable layer and/or a heat sealable layer on a polyethylene core layer. The various layers may optionally be provided with intermediate layers to provide the necessary compatibility between the layers. Preferably the various layers are polyethylene layers. BOPE film and MDOPE film have a higher tensile strength and impact strength than conventional polyethylene film BOPE-film. Further BOPE and MDOPE may be produced with a high transparency. Since the package according to the disclosure is used for preserving produce, transparency of the packing material is important. The customer wishes to ensure himself of the quality and freshness of the produce. BOPE and MDOPE-containing polymer films with a haze of at most 10, preferably at most 5, more preferably at most 3, and most preferably at most 2, as determined by ASTM D 1003 are suitable for the present package. Owing to their higher mechanical strengths, BOPE and MDOPE-containing polymer films may be prepared with a reduced thickness, resulting in a reduced plastic use, and thus reduced costs and a reduced waste. Furthermore, BOPE and MDOPE are 100% recyclable. We have found that this type of material is especially suitable for creating microperforations in a reproducible way with very homogeneous perforations. We have also found that BOPE and MDOPE have a strongly increased CO.sub.2 permeability and ratio, as well as a higher water vapour transmission rate compared to conventional polyethylene. These properties make the material highly suitable for use in the package according to the disclosure. It even makes it possible to adjust the package to the specific produce to be packed.

[0042] Biaxially oriented polyethylene (BOPE) films are known in the art. For instance WO 97/22470 describes BOPE films and its production process. In the examples several films are prepared and oriented. The disclosed resulting properties of the films comprises the Oxygen transmission rate and the water vapour transmission rate. The document is silent on the CO transmission rate of the films.

[0043] It is known that different species of produce and different varieties within a produce species exhibit different respiration rates, documented in literature. The total open area of the perforations for CAP should be determined based on the produce (to be) packed and the transmission properties of the packaging material itself; the transmission rate of the package for each substance is formed by the combination of the transmission rate of the packaging material and the transmission rate through the perforations for the respective substance.

[0044] The package of the present disclosure may suitably be used suitable for any respiring produce such as freshly cut leafy greens, freshly cut vegetables, fruit, herbs, flowers or prepared salads. As mentioned above the BOPE or MDOPE-containing polymer film enables the adjustment to the package of any respiring produce. We have found that this can be done by setting the carbon dioxide transmission rate of the package to at least 1000 ml/24 hrs per 100 gram produce to be packed. The impact of carbon dioxide when it reaches a harmful level on for instance leafy greens such as spinach is much higher than for instance dense vegetables such as green beans or brussels sprouts, because the surface area of spinach per weight is much higher than for green beans. Thus with the present disclosure packages are provided that are suitable both for high demanding produce such as leafy greens, but also for more dense produce such as green beans or brussels sprouts. The parameter of CO.sub.2TR of the package per 100 grams of produce takes into account the differences in density of the produce. In the literature this parameter was not disclosed and its relevance was not recognised.

[0045] Examples of freshly cut leafy greens are lettuce, arugola, spinach, romaine, and combinations hereof.

[0046] For these freshly cut leafy greens a CO.sub.2TR of the package per 100 grams preferably is 1500 ml/24 hrs, more preferably 2000 ml/(24hrs, most preferred 2500 ml/24 hrs.

[0047] Examples of freshly cut vegetables are beans, zucchini, carrots, sprouts, leaks, cauliflower, broccoli, etcetera, and combinations thereof.

[0048] Examples of fresh fruit are berries, apples, pears, tomatoes, peppers, bananas, mango, grapes, stone fruit such as mango, grapes, etcetera, and combinations thereof.

[0049] The package according to the disclosure may also suitable be used for prepared salads. These may comprise freshy-cut leafy greens and/or freshly cut vegetables, and/or fresh fruit.

[0050] As mentioned above, BOPE and MDOPE can be prepared with smaller thickness than conventional polyethylene, because of its higher mechanical strength. In addition to the recyclability of these types of films, these reduced thicknesses have advantages with respect to costs and environmental impact.

[0051] The thickness of the polymer film layer is in the range of 5-200 micrometers, preferably in a range of 10-150 micrometers, more preferably in a range of 15-100 micrometers, even more preferable in a range of 20-75 micrometers, most preferable in a range of 15-50 micrometers.

[0052] The packaging material has a carbon dioxide transmission rate CO.sub.2TR.sub.mat and an oxygen transmission rate O.sub.2TR. The package has a package carbon dioxide transmission rate CO.sub.2TR.sub.pack and an oxygen transmission rate O.sub.2TR.sub.pack and a package transmission ratio .sub.pack=CO.sub.2TR.sub.pack/O.sub.2TR.sub.pack of at least 1,5, preferably at least 2, more preferably at least 3, still more preferably at least 4, e.g. 5 or more.

[0053] Thus the package as a whole provides a high transmission ratio between the transmission rates for oxygen and carbon dioxide.

[0054] The carbon dioxide transmission rate facilitates escape of carbon dioxide and thus reduces elevating CO.sub.2 concentration in the package atmosphere, thus reducing or preventing risks of anaerobic decay processes. Further, CO.sub.2 may dissolve in water, from which it may re-enter the package atmosphere later on, and with which it may react to form carbonic acid which in turn may affect taste and/or composition of food produce stored in the package.

[0055] When the package is closed comprising respiring produce, the oxygen in the package atmosphere is consumed and the oxygen concentration decreases.

[0056] A too-low O.sub.2-concentration may accelerate anaerobic decay processes; however, a too high concentration causes accelerated aging of the produce. Both should be prevented. The oxygen transmission rate O.sub.2TR of the package enables an inflow of oxygen into the package atmosphere, preventing complete consumption of the oxygen.

[0057] An oxygen concentration in a range of typically 1-10%, preferably 2-8% e.g. 3-7% more preferably 4-6% may be preferred to decelerate aging processes (also known as putting the produce to sleep) and maximise shelf life. Such concentrations may be achieved by the one or more perforations forming the package as a CAP. By the one or more perforations the oxygen transmission rate of the package as a whole can be increased.

[0058] Each perforation affects the transmission rate of the package as a whole for oxygen and carbon dioxide. The package transmission ratio .sub.pack facilitates control over the oxygen concentration and the carbon dioxide concentration in the package atmosphere by perforating the material with the one or more perforations. Thus increased inflow of oxygen and increased outflow of carbon dioxide may be balanced by the perforation(s).

[0059] The one or more perforations may be provided as one or more microperforations. The package when formed into the CAP should be devoid of other openings than provided by the one or more perforations for accurate control of the package atmosphere.

[0060] It is noted that the water vapour transmission rate of the package is only insignificantly affected by the open area of microperforations for CAP.

[0061] In an embodiment, the one or more perforations may comprise microperforations having an open area of below 1 square millimetre, preferably below 0.5 square millimetre, e.g. about 0.25 square millimetre or less. Such microperforations facilitate exchange of gases through the packaging material, but hinder contamination of the packed material from outside sources. Such microperforations may be made by (hot) needles. Laser perforation is an effective manner to provide such microperforations fast, reliable, food-safe, and in desired locations. Microperforations also tend not to significantly compromise integrity of the packaging material, in particular if the perforated packaging material comprises a polymeric film. Suitable films may range from a flexible films that can be bent and/or folded multiple times without harm to a rigid film for making a tray.

[0062] Laser drilled microperforations may be approximately round or oblong, having a (largest) diameter in a range of 50-500 micrometres, in particular in a range of 60-400 micrometres, preferably in a range of 70-200 micrometres, more preferably in a range of 80-150 micrometres such as in a range of 90-120 micrometres.

[0063] Determining an oxygen transmission rate and/or a carbon dioxide transmission rate provided by a perforation may comprise determining an open area and a film thickness. In case of a generally round, elliptical of oval perforation the open area may be determined by determining on the basis of one or more diameters determined from the hole, for which camera images may be used. A suitable calculation model is provided in Fishman et al, Mathematical model for perforation effect on oxygen and water vapor dynamics in modified atmosphere packages, J. Food Sci. 61(5):956-961 (1996).

[0064] With properly setting the carbon dioxide transmission rate and the oxygen transmission rate of the package, i.e. the , by choosing the proper packaging material and adding microperforations a CAP can be established. Thus, the one or more perforations perforation provides a perforation carbon dioxide transmission rate CO.sub.2TR.sub.perf and a perforation oxygen transmission rate O.sub.2TR.sub.perf, such that the package carbon dioxide transmission rate CO.sub.2TR.sub.pack is the sum of the perforation carbon dioxide transmission rate CO.sub.2TR.sub.perf and the carbon dioxide transmission rate CO.sub.2TR of the packaging material: CO.sub.2TR.sub.pack=CO.sub.2TR.sub.perf+CO.sub.2TR.sub.mat; and the package oxygen transmission rate O.sub.2TR.sub.pack is the sum of the perforation oxygen transmission rate O.sub.2TR.sub.perf and the oxygen transmission rate O.sub.2TR of the packaging material: O.sub.2TR.sub.pack=O.sub.2TR.sub.perf+O.sub.2TR.sub.mat. The package transmission ratio .sub.pack then is .sub.pack=(CO.sub.2TR.sub.perf+CO.sub.2TR.sub.mat)/(O.sub.2TR.sub.perf+O.sub.2TR.sub.mat). As described above, the package according to the disclosure has .sub.pack of at least 1,5, preferably at least 2, more preferably at least 3, still more preferably at least 4, such as 5 or more.

[0065] The packaging material may have an oxygen transmission rate (O.sub.2TR.sub.mat) of at least 2000 ml/(m.sup.2.Math.24 hrs), preferably at least 3000 ml/(m.sup.2.Math.24 hrs), more preferably at least 4000 ml/(m.sup.2.Math.24 hrs), most preferably at least 5000 ml/(m.sup.2.Math.24 hrs). The oxygen transmission rate is measured in accordance with ASTM D3985 2556 (coulometric method) at a test temperature of 23 C.

[0066] The packaging material may have a carbon dioxide transmission rate (CO.sub.2TR.sub.mat) of at least 15000 ml/(m.sup.2.Math.24 hrs), preferably at least 20000 ml/(m.sup.2.Math.24 hrs), more preferably at least 25000 most preferably at least 30000 ml/(m.sup.2.Math.24 hrs). The carbon dioxide transmission rate is measured in accordance with ISO 2556 (manometric method) at a test temperature of 23 C.

[0067] A package according to the disclosure may also be in the form of a tray and a lidding film sealed to the tray thus closing the package. In that case the lidding film is a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented poly Ethylene (MDOPE)-containing polymer film polymer film.

[0068] A tray package may protect the produce from mechanical harm and/or may collect juices leaking from the produce, thus it is particularly suitable for soft and/or liquid-producing produce like soft fruits, berries, grapes, and/or flowers. Tray packages comprising a barrier material may be particularly robust for such purposes.

[0069] Produce packaged in such tray packages according to the present concepts, may have extended shelf life. The lidding film may be a preferred location for the one or more perforations and it may have a particular influence in determining the transmission ratio of the package. E.g., the lidding film may have the specified carbon dioxide transmission rate and/or oxygen transmission rate of the material.

[0070] A tray formed from a sheet of material comprising one or more layers comprising polyethylene terephthalate (PET) may be strong and light weight. The material may be well recyclable reducing an environmental footprint. In such PET-tray, the material of each of the layers of the formed tray may comprise at least 50%, preferably at least 85%, more preferably at least 95% of amorphous polyethylene terephthalate, which facilitates forming the tray and providing high clarity of it.

[0071] The package may comprise a peripheral sealing rim provided with a layer of an adhesive along the circumference of the tray, preferably along the full circumference of the tray. The adhesive may facilitate sealing a lidding film of another (non-PET) material to the tray.

[0072] The disclosure is further directed to a method for manufacturing a package for preserving respiring produce contained in the package comprising: [0073] i. providing a closed package defining a package volume for containing in the package volume a portion of the respiring produce from a packaging material comprising a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented poly Ethylene (MDOPE)-containing polymer film with a haze of at most 10, preferably at most 5, more preferably at most 3, most preferably at most 2, as determined by ASTM D 1003; and [0074] ii. determining a size, and possibly a number of one or more perforations (3) provided in or to be provided in the packaging material to enable gas exchange between the package atmosphere and the atmosphere surrounding the package to form the package into a Controlled Atmosphere Package (CAP), such that the package has a package carbon dioxide transmission rate (CO.sub.2TR.sub.pack) which is at least 1000 ml/24 hrs per 100 gram produce to be packed, preferably at least 1500 ml/24 hrs, more preferably at least 2000 ml/(24 hrs, most preferred at least 2500 ml/24 hrs.

[0075] Suitable packaging material for the method may have an oxygen transmission rate (O.sub.2TR) of at least 2000 ml/(m.sup.2.Math.24 hrs), preferably at least 3000 ml/(m.sup.2.Math.24 hrs), more preferably at least 4000 ml/(m.sup.2.Math.24 hrs), most preferably at least 5000 ml/(m.sup.2.Math.24 hrs). However, an oxygen transmission rate O.sub.2TR of the material may preferably be less than 15000 ml/(m.sup.2.Math.24 hrs), more preferably less than 10000 ml/(m.sup.2.Math.24 hrs), to facilitate adjustment using the one or more perforations.

[0076] The carbon dioxide transmission rate (CO.sub.2TR) of the suitable packaging material for the method may have at least 10000 ml/(m.sup.2.Math.24 hrs), preferably at least 12000 ml/(m.sup.2.Math.24 hrs), more preferably at least 15000 most preferably at least 20000 ml/(m.sup.2.Math.24 hrs). However, a carbon dioxide transmission rate CO.sub.2TR of the material may preferably be less than 100000 ml/(m.sup.2.Math.24 hrs), more preferably less than 75000 ml/(m.sup.2.Math.24 hrs), to facilitate adjustment using the one or more perforations.

[0077] The method of manufacturing a package for package for preserving respiring produce contained in the package may also be directed to the production of a tray with a lidding film sealed to the tray thus closing the package wherein the lidding film is a Biaxially Oriented Poly Ethylene (BOPE) or a Mono Directed Oriented Poly Ethylene (MDOPE)-containing polymer film polymer film.

[0078] The package containing respiring produce may be closed by hand with a closing device (e.g. tie, clip, tape, elastic band, etc.) and/or by folding and/or knotting. Also or alternatively, the package may be (further) closed by other techniques, e.g. by use of adhesives and/or by welding which may comprise using a hand-held device and/or an automated device which may be comprised in the apparatus. The package may be closed immediately after filling or produce may be filled in the package and the package being closed after a further treatment step and/or conditioning step, e.g. cooling.

[0079] It was found that the use of BOPE or MDOPE-containing polymer film enabled reducing the amount of oxygen in the package below that normally acceptable for CAP where higher-than-desired amounts of oxygen must be accepted to prevent unacceptably high levels of CO.sub.2.

[0080] More importantly, such package enables extending shelf life of respiring produce in CAP packages by several days. This may amount to extending shelf life over 30-100% compared to conventional polymer films used.

[0081] In more detail, in CAP, the oxygen concentration in the package atmosphere may be lowered to a reduced oxygen concentration in order to slow down aging processes, while at the same time ensuring a minimum level of oxygen. Also or alternatively, the carbon dioxide concentration in the package atmosphere may be controlled to ensure a level below becoming harmful. Thus, aging, maturation and/or decay are slowed down and in particular anaerobic processes such as off-smell, decay cell membrane breakdown are prevented. Generally, it is preferred that the equilibrium oxygen concentration and/or carbon dioxide concentration are reached as soon as possible. For that, a combination of CAP and MAP may be used. For the MAP, the initial package atmosphere may be established at or near the time of closing the package by creating in and/or introducing into the package volume an atmosphere modification gas or gas mixture differing from the ambient atmosphere.

[0082] For prolonged storage, most produce benefit from both a low CO.sub.2-concentration and a low O.sub.2-concentration in the package atmosphere, wherein the O.sub.2-concentration is in the range of about 1-10% by volume (% vol), preferably in a range 3-7% vol. In order to maintain such low O.sub.2-concentration, the perforation(s) in the package should provide an open area configured to control inflow of oxygen into the package volume, in particular establishing a minimum inflow to prevent anaerobicity and a maximum inflow to ensure the low oxygen concentration slowing down the metabolic processes of the produce (a.k.a. putting the produce to sleep). This restriction to the open area of the perforation(s) inherently restricts outflow of CO.sub.2 from the package through the perforations, considering that perforations are a-selective with respect to O.sub.2 and CO.sub.2: typically the ratio for the flow of CO.sub.2:O.sub.2 for 1 small laser perforation is approximately 1. The perforations in the package therefore determine simultaneously an upper limit for outflow of CO.sub.2 and inflow of O.sub.2. Manufacturing a CAP package thus forces a compromise between on the one hand raising the outflow of CO.sub.2, which is desired, and on the other hand raising the inflow of O.sub.2, which is undesired.

[0083] A high CO.sub.2TR of the packaging material is therefore beneficial in establishing an improved concentration balance between O.sub.2 and CO.sub.2 in the package atmosphere, since this raises the transmission rate for CO.sub.2 for the CAP package as a whole.

[0084] The package atmosphere may define an equilibrium amount of oxygen and an amount of carbon dioxide which together make up less than 20% vol of the package atmosphere, preferably less than 17% vol such as less than 15% vol or even less than 13% vol.

[0085] It has been found that as a rule-of-thumb, for present-day packaging films for fresh respiring produce, generally in CAP the amounts of O.sub.2 and CO.sub.2 together make up about 21-23% vol of the package atmosphere ({amount O.sub.2}+{amount CO.sub.2}=ca. 21-23% vol of the package atmosphere). In the presently provided package, the transmission ratio of the package facilitates escaping the aforementioned rule of thumb and achieving both a low concentration of O.sub.2 and of CO.sub.2 in the package atmosphere and a low concentration of CO.sub.2 in the combined concentration.

[0086] Most aging processes lead to CO.sub.2 production, causing a build-up in the package atmosphere. An elevated CO.sub.2-concentration may accelerate anaerobic decay processes and should be prevented. However, a too high carbon dioxide transmission rate may prevent a desired deceleration of metabolic processes and associated extension of shelf life. The presently provided ranges are preferred to meet such balance.

[0087] Respiration and most aging processes lead to O.sub.2 consumption, causing a depletion in the package atmosphere. A high O.sub.2TR of the packaging material and/or a high carbon dioxide transmission rate CO.sub.2TR of the packaging material facilitates fine control of oxygen influx and, respectively carbon dioxide outflow, e.g. by precisely establishing a ratio of the packaging material area and the open area of the one or more perforations to achieve the transmission ratio of the package.

[0088] The package volume may be in a range of 2-5 times the volume of the produce in the package, in some cases in a range 3-4 times the volume of the produce in the package. In some cases the package volume may be in range of 5-10 times the produce volume, e.g. 6-8 or 7 times. A larger volume ratio may be in particular used for consumer packages and/or produce that is one or more of hollow, delicate and finely divided like raspberries, cut lettuce, herbs (parsley stalks, thymian sprigs, etc). Package volume unoccupied by produce is generally called headspace.

[0089] The present disclosure is further illustrated by means of the following Examples. These Examples are merely meant for illustration and should not be construed as limitative.

EXAMPLES

Examples 1-13

[0090] Several sachets of a BOPE film according to the claims were provided with produce. The BOPE film was a 5-layer film with the following properties:

[0091] Thickness: 30 micrometers,

[0092] Haze: 2.5 as determined in accordance to AST D 1003

[0093] Tensile strength: MD=80, HD=210 as determined in accordance to AST D882

[0094] Density: 0.937 g/cm.sup.3

[0095] CO.sub.2TR: 30.000 ml/(m.sup.2.Math.24 hrs) as determined in accordance to ISO 2556 at a test temperature of 23 C.

[0096] The results are given in TABLE I below.

Comparative Examples 14-26

[0097] For comparison, the days of good quality after packing is given for the same produce in the same amounts packed in sachets of similar size and volume of conventional polyethylene and BOPP for packing food products. The results are given in TABLE II.

Examples 27-33 Quality and Gas Levels of Packed 150 g Spinach Upon Storage at 6 C.

[0098] 150 g of spinach was packed in sachets (260 mm270 mm) with or without perforations and stored for 20 days at 6 C. On days 2, 6, 9, 14, 17, and day 20 the oxygen (O.sub.2) level, the carbon dioxide (CO.sub.2) level within the sachet and the overall quality were assessed.

[0099] When sachets of BOPE were used, the same film as in Examples 1-14 was used of thickness 40 micrometers. When sachets of BOPP were used the same material (CO.sub.2TR of 3500 ml/m2.Math.24 hrs) as in examples 14-26 was used with a film thickness of 30 micrometers, and provided with an anti-fog coating. The film thicknesses of 40 and 30 micrometers were found to be comparable with respect to the CO.sub.2TR and O.sub.2TR and therefore could be used interchangeably. Also the relevance of an oxygen flush of the filled sachet (with 10% of residual O.sub.2) was assessed. The microperforations when present were applied by a PerfoTec laser micro perforation PER 30 and all sachets were provided with the same perforation pattern. In order to calculate the optimal microperforation pattern the produces' respiration rate was determined beforehand with a

[0100] Fast Respiration Meter System 4.0

[0101] The results are compiled in TABLE III.

[0102] These results show that spinach packed in BOPE with perforations and a CO.sub.2TR per 100 g produce according to the invention provides a shelf-life of at least 20 days. The CO.sub.2 level within these packages remained below 5% over the test period, while the O.sub.2 level remained in the optimal range for this batch of spinach of about 10%. A CO.sub.2 level of above 5% is considered detrimental since it affects the taste and odour of the produce. The positive result was obtained, both in packages that had been flushed with oxygen and packages without flush. In comparison with BOPP packages (shelf-life of 9 days), this is an increase of at least 222%.

[0103] The packages using BOPP however all suffered from CO.sub.2 increase early on in the test period with CO.sub.2 levels above 5%. Also when providing the BOPP packages with perforations, the CO.sub.2 level increased rapidly, causing lowering of the product quality, resulting of a shelf-life of at most 9 days

Examples 34-39 Quality and Gas Levels of Packed 80 g Lambs Lettuce Upon Storage at 6 C.

[0104] 80 g of lambs lettuce was packed in sachets (260 mm270 mm) with or without perforations and stored for 17 days at 6 C. On days 2, 6, 9, 14, and 17 the oxygen (O.sub.2) level, the carbon dioxide (CO.sub.2) level within the sachet and the overall quality were assessed. Also the relevance of an oxygen flush of the filled sachet (with 10% of residual O.sub.2) was assessed. The BOPE and BOPP sachets had the same dimensions, perforation pattern, when present, and were of the same material as examples 27-33.

[0105] The results are compiled in TABLE IV.

[0106] These results show that lambs lettuce packed in BOPE with perforations and a CO.sub.2TR per 100 g produce according to the invention provides a shelf-life of at least 17 days. The CO.sub.2 level within these packages remained below 5% over the test period, while the O.sub.2 level remained in the optimal range for this batch of lambs lettuce of about 10%. A CO.sub.2 level of above 5% is considered detrimental since it affects the taste and odour of the produce. The positive result was obtained, both in packages that had been flushed with oxygen and packages without flush. In comparison with BOPP packages (shelf-life of 6 days), this is an increase of at least 283%.

[0107] Although the packages using BOPP fulfilled the CO.sub.2TR per 100 g produce requirement, the packages suffered from CO.sub.2 increase above 5% after 2 days. Also when providing the BOPP packages with perforations, the CO.sub.2 level increased to above 5% after day 9, which is an improvement compared to non-perforated BOPP packages, but still not good enough, causing yellow leaves and rot appearing on day 9. The lowering of the product quality, results in a shelf-life of at most 8 days when using BOPP.

Examples 40-45 Quality and Gas Levels of Packed 150 g Arugola Upon Storage at 6 C.

[0108] 150 g of arugola was packed in sachets (260 mm270 mm) with or without perforations and stored for 17 days at 6 C. On days 2, 6, 9, 14, and 17 the oxygen (O.sub.2) level, the carbon dioxide (CO.sub.2) level within the sachet and the overall quality were assessed. Also the relevance of an oxygen flush of the filled sachet (with 10% of residual O.sub.2) was assessed. The BOPE and BOPP sachets had the same dimensions, perforation pattern when present, and were of the same material as examples 27-33.

[0109] The results are compiled in TABLE V.

[0110] These results show that arugola packed in BOPE with perforations and a CO TR per 100 g produce according to the invention provides a shelf-life of at least 17 days. The CO.sub.2 level within these packages remained below 5% over the test period, while the O.sub.2 level remained in the optimal range for this batch of arugola lettuce of about 15%. A CO.sub.2 level of above 5% is considered detrimental since it affects the taste and odour of the produce. The positive result was obtained, both in packages that had been flushed with oxygen and packages without flush. In comparison with BOPP packages (shelf-life of 6 days), this is an increase of at least 283%.

[0111] The packages using BOPP suffered from CO.sub.2 increase above 5% after a few days. In addition to the detrimental CO.sub.2 level, the O.sub.2 level could not be kept optimal and reduced to 0% over the test period. Also when providing the BOPP packages with perforations, the CO.sub.2 level increased to above 5% after day 2, the reduction of the O.sub.2 level was less pronounced but still reduced to 0% at day 9, resulting in yellowing and rot. The lowering of the product quality, results in a shelf-life of at most 8 days when using BOPP.

TABLE-US-00001 TABLE I Days of good quality after packing produce in BOPE upon storage at 6 C. Total CO.sub.2TR CO.sub.2TR of (film plus perfs) Total CO.sub.2TR Days of good Example CO.sub.2TR perforations per sachet) per 100 gram quality after No Produce sachet per sachet (ml/24 h) produce packing 1 Spinach 150 g 4002 400 4402 2935 14 2 Spinach 150 g 4002 400 4402 2935 14 3 Spinach 200 g 4368 600 4968 2484 14 4 Spinach 300 g 4730.4 900 5630.4 1877 14 5 Spinach 500 g 6552 1200 7752 1550 14 6 Salad Mix 500 g 6393.6 500 6893.6 1379 12 7 Salad Mix 570 g 6571.2 700 7271.2 1276 12 8 Salad Mix 700 g 6903 900 7803 1115 12 9 Salad Mix 1000 g 15019.2 1200 16219.2 1622 12 10 Lollo Bionda 250 g 4989.6 500 5489.6 2196 12 11 Lollo Bionda 2x 250 g 4972.8 500 5472.8 2189 12 12 Lollo Bionda 300 g 5346 600 5946 1982 12 13 Lollo Rosso 250 g 4989.6 500 5489.6 2196 12

TABLE-US-00002 TABLE II Days of good quality after packing produce in conventional packing material upon storage at 6 C. Days good Days good quality quality after after packing packing with Ex. No Product withh BOPP conventional PE 14 (comp) Spinach 150 g 7 9 15 (comp) Spinach 150 g 7 9 16 (comp) Spinach 200 g 7 9 17 (comp) Spinach 300 g 7 9 18 (comp) Spinach 500 g 7 9 19 (comp) Salad Mix 500 g 6 7 20 (comp) Salad Mix 570 g 6 7 21 (comp) Salad Mix 700 g 6 7 22 (comp) Salad Mix 1000 g 6 7 23 (comp) Lollo Bionda 250 g 6 8 24 (comp) Lollo Bionda 2x 250 g 6 8 25 (comp) Lollo Bionda 300 g 6 8 26 (comp) Lollo Rosso 250 g 6 8

TABLE-US-00003 TABLE III Quality and gas levels of 150 g packed Spinach upon storage for 20 days at 6 C. Total Flush CO.sub.2TR Exam- CO.sub.2TR.sub.Perforations (24% per 100 g ple Film per sachet O.sub.2) produce No. material (ml/24 h) (Y/) (ml/24 h) Comments 27 BOPE 468 y 3276 Still on spec after day 20 28 BOPE 468 3276 Still on spec after day 20 29 BOPP 327.6 CO.sub.2 level above (comp) 5% after day 2, Rotten leaves appear at day 9 30 BOPP 468 y 795.6 CO.sub.2 level above (comp) 5% after day 2, starts to rot at day 9 31 BOPP y 327.6 CO.sub.2 level above (comp) 5% after day 2 32 BOPP y 327.6 CO.sub.2 level above (comp) 5% after day 3 33 BOPP 468 795.6 CO.sub.2 level above (comp) 5% after day 2

TABLE-US-00004 TABLE IV Quality and gas levels of 80 g packed lambs lettuce upon storage for 17 days at 6 C. Total Flush CO.sub.2TR Ex- CO.sub.2TR.sub.Perforations (24% per 100 g ample Film per sachet O.sub.2) produce No. material (ml/24 h) (Y/) (ml/24 h) Comments 34 BOPE 468 y 5733 CO.sub.2 still below 5% after day 17 Still on spec after 17 days 35 BOPE 468 5733 CO.sub.2 below 4% after day 17 Still on spec after 17 days 36 BOPP 1750 CO.sub.2 level above (comp) 5% after day 3, On day 6 end of life time 37 BOPP 468 y 2218 CO.sub.2 level above (comp) 5% after day 9, and sharp decrease O2 level 38 BOPP y 1750 O.sub.2 level (comp) increases from 12 to 17% over the test period, the optimal level being 10% 39 BOPP 468 2218 CO.sub.2 level above (comp) 5% after day 9 Yellow leaves and rot appear after day 9

TABLE-US-00005 TABLE V Quality and gas levels of 150 g packed arugola upon storage for 17 days at 6 C. Total Flush CO.sub.2TR Ex- CO.sub.2TR.sub.Perforations (24% per 100 g ample Film per sachet O.sub.2) produce No. material (ml/24 h) (Y/) (ml/24 h) Comments 40 BOPE 468 y 3276 Both CO.sub.2 and O.sub.2 level remain between 5-7% during storage period of 17 days Still on spec after 17 days 41 BOPE 468 3276 CO.sub.2 remains between 4-6% during storage period of 17 days, O.sub.2 level decreases from 16-10% over 17 days of storage 42 BOPP 327.6 Still on spec (comp) after 17 days CO.sub.2 level above 5% after day 2, O.sub.2 level decreases to 0% at day 17 Yellowing and rotten leaves present on day 9 43 BOPP 468 y 795.6 CO.sub.2 level (comp) above 5% after day 2, O.sub.2 level decreases to 0% at day 9 44 BOPP y 327.6 Sharp (comp) increase of CO.sub.2 level to above 5% after day 2, Sharp decrease of O.sub.2 level after day 2 to 0% at day 17