Title of Invention	A METHOD OF REDUCING GAS PERMEABILITY OF POLYMERIC CONTAINERS
Abstract	A method for reducing gas permeability of shaped thermoplastic polymeric articles wherein the polymer from which the article is formed in selected from the group consisting of polyesters, polycarbonates, polyetherimides and polyethersulfones and wherein the method comprises the steps of (1) incorporating into the polymer an amount of a of a barrier-enhancing additive or a mixture of barrier-enhancing additives effective to reduce gas permeability and selected from the group consisting of:

Title of Invention

A METHOD OF REDUCING GAS PERMEABILITY OF POLYMERIC CONTAINERS

Abstract

A method for reducing gas permeability of shaped thermoplastic polymeric articles wherein the polymer from which the article is formed in selected from the group consisting of polyesters, polycarbonates, polyetherimides and polyethersulfones and wherein the method comprises the steps of (1) incorporating into the polymer an amount of a of a barrier-enhancing additive or a mixture of barrier-enhancing additives effective to reduce gas permeability and selected from the group consisting of:

Full Text	FORM 2 THE PATENTS ACT 1970 [39 OF 1970] COMPLETE SPECIFICATION [See Section 10, Rule 13] "A METHOD OF REDUCING GAS PERMEABILITY OF POLYMERIC CONTAINERS" E.I.DU PONT DE NEMOURS AND COMPANY, a Delaware corporation, of 1007 Market Street, Wilmington, Delaware 19898, United Stares of America, The following specification particularly describes and ascertains the nature of the invention and the manner in which it is to be performed:- CROSS REFERENCE(S) TO RELATED APPLICATION(S) This application claims priority benefit from U.S. provisional patent application no. 60/148,537 filed August 12, 1999. BACKGROUND OF THE INVENTION The present invention is a polymer composition and method for improving the gas barrier performance of polymeric containers and films, and particularly containers for food and beverages which are molded from thermoplastic polyester polymers. More particularly, the invention is a polymer composition and method for reducing the permeability of gases through molded polymeric containers, sheets and films by incorporating into the polymer from which the container, sheet or film is formed an effective amount of a barrier-enhancing additive of the type described herein. The addition of small amounts of molecular additives to a base polymer can result in antiplasticization of the polymer whereby the modulus of the polymer increases below its glass transition temperature and its barrier to gas permeability can improve. For example, Robeson describes the use of phenyl-2-naphthyl amine in polysulfone [Robeson, L.M.; Faucher, J.A., J. Polym. Sci., Part B 7, 35-40 (1969)] and various polychlorinated aromatic molecules in polycarbonate and in polyvinyl chloride [Robeson, L.M., Polym. Eng, Sci. 9, 277-81 (1969)]. Maeda and Paul [Maeda, Y.; Paul, D.R., J. Polym. Sci., Part B: Polym. Phys, 25, 981-1003 (1987)] disclose the use of tricresyl phosphate in polyphenylene oxide to lower the sorption of carbon dioxide (and therefore its permeability). However, the need exists to improve the gas barrier performance of polymer resins of the type currently used for molded containers for food and beverages, and, in particular, poly(ethylene) terephthalate (PET) thermoplastic polyester polymers used for producing injection stretch blow molded bottles for packaging water, carbonated soft drinks and beer. Additives selected from 4-hydroxybenzoates and related molecules of the type described herein have not been suggested. SUMMARY OF THE INVENTION The present invention and the inventive features described herein reside in the discovery of certain barrier-enhancing additives for thermoplastic polymers. The invention is a polymer composition that contains one or more of the additives and a method for reducing gas permeability of shaped polymeric articles produced from such a composition, such articles being generally selected from containers, sheets and films. The method comprises incorporating into the polymer an effective amount of a barrier-enhancing additive, or a mixture of barrier-enhancing additives, selected from the group consisting of: (a) monoesters of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (A) wherein R is C1 - C8 alkyl, benzyl, phenyl or naphthyl; Ar is substituted or unsubstituted phenylene or naphthalene; or formula (AA) where M is a cation such as, but not limited to, sodium, ammonium, tetraalkyl ammonium, potassium, calcium, magnesium or zinc; (b) diesters of hydroxybenzoic acid of the formula (B) wherein Ar is as defined above, and R1 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above. (c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C) wherein R and Ar are as defined above; or formula (CC) where M is as defined above. (d) diamides of hydroxybenzoic acid of the formula (D) wherein Ar is as defined above, and R2 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (DD) where M is as defined above. where Ar is as defined above and R3 is C1 - C8 alkyl, C1 - C8 dialkyl, (CH2CH2O)kCH2CH2 where k is 1 or greater, benzyl, phenyl or naphthyl, or formula (EE) where M is as defined above. As used herein, an effective amount, i.e., the preferred range of barrier enhancing additive, is from 0.1% by wt. to 20% by wt. of the base polymer comprising the polymeric article. Polymeric articles, and particularly extruded film or injection stretch blow molded polyester (e.g., PET) bottles, which contain one or more of the barrier-enhancing additives described herein, exhibit substantially reduced oxygen and carbon dioxide permeability values when measured according to ASTM D3985 and water vapor permeability values when measured according to ASTM F1249 in comparison to corresponding polymeric articles which contained no barrier-enhancing additives. DETAILED DESCRIPTION OF THE INVENTION The present invention resides in the discovery that oxygen, water vapor and carbon dioxide (CO2) permeability values for shaped polymeric containers and films can be substantially reduced by incorporating into the base polymer from which the articles are formed from about 0.1% by wt. up to about 20% by wt. of a barrier-enhancing additive of the type defined herein. A uniform physical blend, or mixture, is prepared comprising the base polymer and one or more barrier-enhancing additives in the desired concentrations. As used herein with reference to the invention, the term "composition" is intended to mean a physical blend or mixture. Water-sensitive base polymers, such as, for example, polyesters should preferably be thoroughly dried by heating under air or nitrogen flow or vacuum as known to those experienced in the art. The mixture is then heated and extruded or molded at a sufficiently high temperature to melt the base polymer and provide for sufficient mixing of the additive or mixture of additives within the base polymer matrix. By way of example using PET, such melt temperature ranges from about 255°C to 300°C. The composition thus produced comprises the barrier-enhancing additive (or mixture of such additives) substantially in its (their) original molecular form; that is, only small amounts of barrier-enhancing additive have been observed to react with the base polymer via trans-esterification or other reaction mechanism typical of the functional groups present. It is preferred to prepare and extrude or mold the polymer composition under conditions of relatively low temperature and processing residence time which thereby minimizes the opportunity for the barrier-enhancing additives to react with the base polymer. Best performance in terms of desirable mechanical properties of polymeric containers and films produced according to the invention is achieved when no more than about 10% of the gas barrier-enhancing additive has reacted with the base polymer. As a consequence of any reaction of a gas barrier-enhancing additive within the scope of the invention with a base polymer, the molecular weight of the starting base polymer may decrease. The gas barrier-enhancing additives found to be most suitable for carrying out the invention are selected from the group consisting of: (a) monoesters of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (A) wherein R is C1 - C8 alkyl, benzyl, phenyl or naphthyl; Ar is substituted or unsubstituted phenylene or naphthylene; or formula (AA) where M is a cation such as, but not limited to, sodium, ammonium, tetraalkyl ammonium, potassium, calcium, magnesium or zinc; (b) diesters of hydroxybenzoic acid of the formula (B) wherein Ar is as defined above, and R1 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above. (c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C) wherein R and Ar are as defined above; or formula (CC) where M is as defined above. (d) diamides of hydroxy benzoic acid of the formula (D) wherein Ar is as defined above, and R2 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (DD) where M is as defined above. (e) ester-amides of hydroxybenzoic acid of the formula (E) where Ar is as defined above and R3 is C1 - C8 alkyl, C1 - C8 dialkyl, (CH2CH2O)k(CH2CH2, where k is 1 or greater, benzyl, phenyl or naphthyl, or formula (EE) where M is as defined above. The above-defined barrier-enhancing additives can be obtained from commercial suppliers or they can be synthesized using established procedures. Base polymers most suitable for use in practicing the invention comprise thermoplastic homopolymers, copolymers (both block and random), and blends of such thermoplastic polymers. Most suitable are polyester homopolymers and copolymers. Among suitable polyester base polymers are those polymers which contain structural units derived from one or more organic diacids (or their corresponding esters) selected from the group consisting of terephthalic acid, isophthalic acid, naphthalene dicarboxylic acids, hydroxybenzoic acids, hydroxynaphthoic acids, cyclohexane dicarboxylic acids, succinic acid, glutaric acid, adipic acid, sebacic acid, 1,12-dodecane dioic acid and the derivatives thereof, such as, for example, the dimethyl, diethyl, or dipropyl esters or acid chlorides of the dicarboxylic acids and one or more diols selected from ethylene glycol, 1,3-propane diol, nathphalene glycol, 1,2-propanediol, 1,2-, 1,3-, and 1,4-cyclohexane dimethanol, diethylene glycol, hydroquinone, 1,3-butane diol, 1,5-pentane diol, 1,6-hexane diol, triethylene glycol, resorcinol, and longer chain diols and polyols which are the reaction products of diols or polyols with alkylene oxides. In a preferred embodiment of the invention the polyester base polymer is polyethylene terephthalate (PET), which includes PET polymer which has been modified with from about 2 mole% up to about 5 mole% of isophthalate units. Such modified PET is known as "bottle grade" resin and is available commercially as Melinar® Laser+ polyethylene terephthalate brand resin (E. I. du Pont de Nemours and Company, Wilmington, DE). As used hereinafter in illustrating the invention, the term PET will refer to commercially available "bottle grade" polyester resin. Preparation of Film and Container Samples Film samples are indicative of the improved gas barrier properties obtainable from the invention. Such film samples were generated from physical blends of a base polymer and a selected additive from among those described herein, and the samples were either compression molded or extrusion cast using a co-rotating twin screw extruder with a slit die, typically having a 0.38 mm gap, a quench roll, and a vacuum port on the front barrel section, with barrel, adapter, and die temperatures set at 240°C to 275 °C depending on the polymer composition being used. Melt temperatures were measured with a thermocouple, and, for samples prepared using a twin screw extruder, melt temperatures were typically about 15°C to 20°C above the set temperature. In a few instances as noted, a transfer line, in which static mixers were installed within the line in place of a compounding screw, was used along with a slit die. Films were typically 0.05 to 0.25 mm thick. The thick films were subsequently stretched biaxially simultaneously to 3.5X by 3.5X using a Long stretcher at 90°C, 9000%/minute unless otherwise noted For fabricating bottles, 26g preforms were injection molded using a Nissei ASB 50 single stage injection stretch blow molding machine with barrel temperatures set at about 265°C and with a total cycle time of about 30 seconds. The preforms were immediately blown into 500 mL round-bottomed bottles with a blow time of 5 seconds. All other pressure, time and temperature set-points were typical for commercially available PET bottle resin. Tensile bars 1/8" thick were molded using a 6oz. injection molding machine with the following machine set-up: barrel temp: 255°C, mold temp: 20°C/20°C, cycle time: 20 sec/20 sec, injection pressure: 5.5 MPa, RAM speed: fast, screw speed: 60 rpm, and back pressure: 345 kPa. Analytical Procedures NMR Spectrometry Samples for 1H NMR were dissolved in tetrachloroethane-d2 at 130°C. Spectra were acquired at 120°C at 500 MHz. Thermal Analysis Differential Scanning Calorimetric data were acquired at 2°/min on a T A Instruments calorimeter. Permeability Oxygen permeability values (OPV) were measured for each sample according to ASTM procedure D3985 at 30°C, 50% RH on an Ox-Tran 1000 instrument from Modern Controls, Inc. Carbon dioxide permeability was measured at 25 °C and 0% RH on a Permatran CIV instrument, also from Modern Controls, Inc. Water vapor permeability was measured at 37-38°C, 100% RH on a Permatran-W600 instrument, also from Modern Controls, according to ASTM procedure F1249. Intrinsic Viscosity Intrinsic viscosity values were determined from 0.4 wt% solution of polymers or polymer blends in a 1:1 (by weight) mixture of methylene chloride and trifluoroacetic acid at 20°C. EXAMPLES Example 1 Films comprising commercially available PET resin (Melinar® Laser+ PET brand resin) as the base polymer plus a barrier additive were prepared by a variety of methods as follows: melt pressing (M), extrusion compounding through a slit die (E), and transfer line mixing (T) into a slit die, and noted below in the table. Compositions are indicated in Table 1. After extrusion, films were simultaneously biaxially stretched to 3.5X by 3.5X at 90°C and at a rate of 9000%/min. Oxygen permeation values (OPV) were measured according to ASTM procedure D3985 at 30° C, 50% relative humidity. Weight percent of the additive in.the resin was assayed by NMR; where such analysis was not possible, nominal values (i.e., amounts initially mixed into the resin) are noted. In each case, both in unstretched and stretched films, the OPV was lower in films which contained a barrier-enhancing additive according to the invention than typical PET values (Control values, Table 1). OPV units are cc-mils/100 sq. in-24 hr-atm. Table 1 Sample Preparation* Additive Wt% (NMR) OPV: Unstretched OPV: Stretched Control E None 0 11.08 7.23 A M Methyl 4-hydroxybenzoate 2.48 7.07 3.48 B T Methyl 4-hydroxybenzoate 5.74 3.76 3.56 C T Methyl 4-hydroxybenzoate 3.49 7.14 3.69 D T Methyl 4-hydroxybenzoate 1.55 8.17 4.70 E T Methyl 4-hydroxybenzoate 0.66 5.91 F E Ethyl 4-hydroxybenzoate 3.71 5.42 4.14 G E n-Propyl 4-hydroxybenzoate 2.90 7.91 4.74 H E i-Propyl 4-hydroxybenzoate 6.00 (nominal) 4.01 I M Benzyl 4-hydroxybenzoate 5.88 (nominal) 8.87 3.99 J M Phenyl 4-hydroxybenzoate 5.55 (nominal) 7.71 3.82 K E Phenyl hydroxynaphthoate 5 (nominal) 8.49 4.47 * Preparation methods: E = extrusion compounded then extrusion through a slit die to make film; M = melt-pressed film; T = transfer line with static mixers then extrusion through a slit die to make film. ** For unstretched PET film, the control OPV is the mean of values for seven different samples, each run in duplicate; the standard deviation is 0.49. For stretched film, the control OPV is the mean of values for 27 different samples, each run in duplicate; the standard deviation is 0.41. Example 2 Films prepared from commercially available PET resin (Melinar® Laser+ brand PET resin) which contained zero or nominally 2 wt% of the sodium salt of methyl 4-hydroxybenzoate were extruded using a twin screw extruder. Oxygen permeability values were determined for both as-cast and biaxially stretched films, as in Ex. 1. Films were stretched to 3.5X by 3.5X at 9000%/min, 100°C. The OPV for the stretched film containing the additive was 5.18 cc-mils/100 sq. in-24 hr-atm stretched, versus 6.56 for stretched PET film without an additive; the additive therefore produced a 26.6% improvement in oxygen barrier performance. Example 3 Poly(propylene terephthalate) ('3GT) films containing zero and nominally 3 wt% methyl 4-hydroxybenzoate ('MHB') were prepared using a twin screw extruder and a barrel setting of 240°C. Films containing no MHB and nominally 3 wt% MHB were stretched 3X by 3X at 55°C and 53 °C respectively. Oxygen permeability values for the 3GT films containing MHB were 4.72 cc-mil/100 sq. in-24 hr-atm for cast film and 3.59 cc-mil/100 sq. in-24 hr-atm for stretched film, versus the 3GT control OPV values of 8.56 for as-cast film and 5.30.for stretched film. Water vapor permeability at 38°C for as-cast films containing MHB was 2.22 g-mil/100 sq. in-24 hr and 1.95 g-mil/100 sq. in-24 hr for stretched film, versus the 3GT control values of 3.50 for as-cast film and 2.24 for stretched film. Example 4 A blend of MHB with PET (IV 0.86) was prepared via twin-screw extrusion at 245°C. The resulting blend, which was a concentrate, had an IV of 0.86 dL/g, and contained 6.9% MHB by NMR analysis. The blend was dried overnight at 100°C under vacuum and combined with standard commercial PET bottle resin (IV 0.83 dL/g, dried 6 hours at 150°C). 26g sample preforms were then injection molded using a Nissei ASB 50 single stage injection stretch blow molding machine, using barrel temperatures of about 265°C and a total cycle time of approximately 30 seconds. The preforms were immediately blown into 500 mL round-bottomed bottles with a blow time of 5 seconds. All other pressure, time and temperature set-points were typical for standard PET bottle resin. A control set of bottles made only of the standard PET bottle resin (IV 0.83, dried 6 hours at 150°C) was prepared under the same conditions. The oxygen permeation value for panels cut from bottles containing 1.97 wt% methyl 4-hydroxybenzoate ('MHB') was determined to be 3.69 cc-mils/100 sq. in-24 hr-atm versus 5.73 for a control PET bottle panel. Carbon dioxide permeation values were 9.65 cc-mil/100 sq. in-24 hr-atm. for the bottle with MHB and 14.62 for the control panel. Example 5 Commercially available PET film containing 4 wt% MXD-6 6007 nylon (Mitsubishi Gas Chemical Corp.) and, nominally, 3 wt% MHB was extruded along with a PET control film. The films were biaxially stretched 3.5X by 3.5X as in Example 1. The OPV for the film containing the additives was 2.59 cc-mils/100 sq. in-24 hr-atm, versus the control film's OPV of 7.14. Example 6 A diester of p-hydroxybenzoic acid ('HBA') (corresponding to Formula B where R1 = CH2CH2) was synthesized from the reaction of stoichiometric mixtures of HBA and ethylene glycol in diphenyl ether with the catalyst butyl stannoic acid. PET films containing 0 and 4.55 wt% of this diester were extruded and then stretched as in Example 1. The OPV of the film containing the diester was 3.93 cc-mils/100 sq. in-24 hr-atm, and the OPV of the PET film without the diester was 7.32 cc-mils/100 sq. in-24 hr-atm. Example 7 The benzamide of HBA (corresponding to Formula C where R = phenyl) was synthesized from the reaction of MHB with benzylamine. An extruded PET film containing a nominal 3 wt% of this benzamide and stretched as in Example 1 exhibited an OPV of 5.00 cc-mil/100 sq. in-24 hr-atm, vs. a PET control film which had an OPV of 6.94. Example 8 The diamide of HBA (corresponding to Formula D where R1 = CH2CH2) was synthesized from the reaction of 4-acetoxybenzoyl chloride with ethylene diamine, followed by basic hydrolysis of the acetate groups. An extruded PET film containing a nominal 3 wt% of this diamide and stretched as in Example 1 exhibited an OPV of 5.46 cc-mil/100 sq. in-24 hr-atm whereas a PET control film exhibited an OPV of 7.79. Example 9 A diester of HBA and triethylene glycol was synthesized from the reaction of stoichiometric mixtures of HBA and triethylene glycol in diphenyl ether with the catalyst butyl stannoic acid. PET film containing 6.49 wt% of this diester (determined by NMR) was extruded and stretched as in Example 1. The OPV for this film was 4.0 cc-mil/100 sq. in-24 hr-atm whereas a PET control film exhibited an OPV of 7.04. Example 10 A blend of 97 wt% dried PET resin (Melinar® Laser+ brand PET resin) and 3 wt% methyl 4-hydroxybenzoate was mixed thoroughly and added to the hopper of a 6 oz. injection molding machine. Standard 1/8" thick tensile bars were molded with the following machine set-up: barrel temp 255°C, mold temp: 20°C/20°C, cycle time: 20 sec/20 sec, injection pressure: 5.5 MPa, RAM speed: FAST, screw speed: 60 rpm, and back pressure: 345 kPa. Intrinsic viscosity was measured on sections which were cut from the center of the bars using a 0.4% solution in 1:1 TFA: CH2Cl2 at 19°C. The I.V. was 0.73 dL/g vs. a control PET resin sample molded under identical conditions which had an I.V. of 0.73 dL/g. In contrast, the I.V. of the bottle from Example 4, containing 1.97 wt% MHB and prepared from a pre-compounded MHB/PET concentrate, was 0.464 dL/g, and the control PET bottle I.V. was 0.76 dL/g. This example demonstrates that degradation of the polymer composition's molecular weight (as evidenced by I.V.) can be avoided by selection of appropriate processing conditions. Example 11 Laser+ PET films containing 0 to 3.46 wt% MHB were prepared by extrusion compounding. Two of these were also biaxially stretched as in Example 1. Water vapor permeabilities (g-mil/100 sq. in - 24 hr) at 38°C, 100% relative humidity are tabulated below. MHB Content (wt%) Water Vapor Permeability, As-Cast Film Water Vapor Permeability, Stretched Film 0 4.31 2.43 0.56 3.87 — 1.91 3.42 1.69 3.46 2.93 — Example 12 Films of Lexan® 134r polycarbonate, Ultem® 1000 polyetherimide (both manufactured by General Electric), and Radel® polyethersulfone (manufactured by Boedeker Plastics, Inc.) containing 0 or nominally 5 wt% n-propyl p-hydroxybenzoate (PUB) were melt-pressed at 260,270, and 270°C, respectively. Oxygen permeabilities (OPV) at 30°C are tabulated below. Polymer OPV, no PHB (cc-mil/100sq. in. 24 hr) OPV,nom.5 wt% PHB (cc-mil/100 sq. in. 24hr) Lexan® 134r polycarbonate 232.5 138.7 Ultem® 1000 polyetherimide 48.05 24.45 Radel® polyethersulfone 89.79 52.11 Example 13 Films of a copolymer of composition 7.4% poly(isosorbide terephthalate)-co-92.6% poly(ethylene terephthalate), prepared according to U.S. Patent No. 5,959,066, containing 0 to 3.85 wt% MHB were prepared by extrusion compounding, then biaxially stretched 3.5X by 3.5X at 90°C (95°C for 0% MHB), 9000%/min. Oxygen permeabilities are tabulated below. MHB Wt% OPV (cc-mil/100 sq. in/24 hr-atm) 0 8.22 0.70 8.02 2.24 5.57 3.85 3.98 We Claim: 1. A method for reducing gas permeability of shaped thermoplastic polymeric articles wherein the polymer from which the article is formed in selected from the group consisting of polyesters, polycarbonates, polyetherimides and polyethersulfones and wherein the method comprises the steps of (1) incorporating into the polymer an amount of a of a barrier-enhancing additive or a mixture of barrier-enhancing additives effective to reduce gas permeability and selected from the group consisting of: (a) monoesters of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (A) wherein R is C1 - C4 alkyl, benzyl, phenyl or naphthyl; Ar is substituted or unsubstituted phenylene or naphthylene; or formula (AA) where M is a cation such as, but not limited to, sodium, ammonium, tetraalkyl ammonium, potassium, calcium, magnesium or zinc; (b) diesters of hydroxybenzoic acid of the formula (B) wherein Ar is as defined above, and R1 is C1-C4 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above. (c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C) wherein R and Ar are as defined above; or formula (CC) where M is as defined above. (b) diesters of hydroxybenzoic acid of the formula (B) wherein Ar is as defined above, and R1 is C1-C4 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above. (c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C) wherein R and Ar are as defined above; or formula (CC) where M is as defined above. (d) diamides of hydroxybenzoic acid of the formula (D) wherein Ar is as defined above, and R2 is C1 - C4 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (DD) where M is as defined above. (e) ester-amides of hydroxybenzoic acid of the formula (E) where Ar is as defined above and R3 is C1 - C4 alkyl, C1 - C8 dialkyl, (CH2CH2O)kCH2CH2 where k is 1 or greater, benzyl, phenyl or naphthyl, or formula (EE) where M is as defined above by first forming a physical mixture comprising the polymer and one or more of the gas barrier enhancing additives, (2) heating the mixture to a temperature sufficiently high to melt the polymer but low enough to maintain the one or more gas barrier enhancing additives substantially in its or their original molecular form, and (3) forming the article. 2. The method as claimed in Claim 1, wherein the barrier-enhancing additive or mixture of barrier-enhancing additives is incorporated into the polymer by physically mixing the components together and then extruding the resulting mixture through an extruder whereby the total concentration of barrier-enhancing additive in the extruded composition is from 0.1% by wt. up to 20% by wt. of the composition. 3. The method as claimed in Claim 2, wherein the polymer comprising the container, sheet or film is selected from thermoplastic homopolymers, random or block copolymers and a blend or blends of such homopolymers and copolymers. 4. The method as claimed in Claim 3, wherein the thermoplastic homopolymer or random or block copolymer is a polyester homopolymer or copolymer. Dated this 11th day of January, 2002 [RANJNA MEHTA-DUTT] OF REMFRY & SAGAR ATTORNEY FOR THE APPLICANTS

Full Text

FORM 2 THE PATENTS ACT 1970 [39 OF 1970] COMPLETE SPECIFICATION
[See Section 10, Rule 13]
"A METHOD OF REDUCING GAS PERMEABILITY OF
POLYMERIC CONTAINERS"
E.I.DU PONT DE NEMOURS AND COMPANY, a Delaware corporation, of 1007 Market Street, Wilmington, Delaware 19898, United Stares of America,
The following specification particularly describes and ascertains the nature of the invention and the manner in which it is to be performed:-

CROSS REFERENCE(S) TO RELATED APPLICATION(S)
This application claims priority benefit from U.S. provisional patent application no. 60/148,537 filed August 12, 1999.
BACKGROUND OF THE INVENTION
The present invention is a polymer composition and method for improving the gas barrier performance of polymeric containers and films, and particularly containers for food and beverages which are molded from thermoplastic polyester polymers. More particularly, the invention is a polymer composition and method for reducing the permeability of gases through molded polymeric containers, sheets and films by incorporating into the polymer from which the container, sheet or film is formed an effective amount of a barrier-enhancing additive of the type described herein.
The addition of small amounts of molecular additives to a base polymer can result in antiplasticization of the polymer whereby the modulus of the polymer increases below its glass transition temperature and its barrier to gas permeability can improve. For example, Robeson describes the use of phenyl-2-naphthyl amine in polysulfone [Robeson, L.M.; Faucher, J.A., J. Polym. Sci., Part B 7, 35-40 (1969)] and various polychlorinated aromatic molecules in polycarbonate and in polyvinyl chloride [Robeson, L.M., Polym. Eng, Sci. 9, 277-81 (1969)]. Maeda and Paul [Maeda, Y.; Paul, D.R., J. Polym. Sci., Part B: Polym. Phys, 25, 981-1003 (1987)] disclose the use of tricresyl phosphate in polyphenylene oxide to lower the sorption of carbon dioxide (and therefore its permeability). However, the need exists to improve the gas barrier performance of polymer resins of the type currently used for molded containers for food and beverages, and, in particular, poly(ethylene) terephthalate (PET) thermoplastic polyester polymers used for producing injection stretch blow molded bottles for packaging water, carbonated soft drinks and beer. Additives selected from 4-hydroxybenzoates and related molecules of the type described herein have not been suggested.

SUMMARY OF THE INVENTION
The present invention and the inventive features described herein reside in the discovery of certain barrier-enhancing additives for thermoplastic polymers. The invention is a polymer composition that contains one or more of the additives and a method for reducing gas permeability of shaped polymeric articles produced from such a composition, such articles being generally selected from containers, sheets and films.
The method comprises incorporating into the polymer an effective amount of a barrier-enhancing additive, or a mixture of barrier-enhancing additives, selected from the group consisting of:
(a) monoesters of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (A)

wherein R is C1 - C8 alkyl, benzyl, phenyl or naphthyl; Ar is substituted or unsubstituted phenylene or naphthalene; or formula (AA) where M is a cation such as, but not limited to, sodium, ammonium, tetraalkyl ammonium, potassium, calcium, magnesium or zinc;
(b) diesters of hydroxybenzoic acid of the formula (B)

wherein Ar is as defined above, and R1 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above.
(c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C)

wherein R and Ar are as defined above; or formula (CC) where M is as defined above.
(d) diamides of hydroxybenzoic acid of the formula (D)

wherein Ar is as defined above, and R2 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (DD) where M is as defined above.

where Ar is as defined above and R3 is C1 - C8 alkyl, C1 - C8 dialkyl, (CH2CH2O)kCH2CH2 where k is 1 or greater, benzyl, phenyl or naphthyl, or formula (EE) where M is as defined above. As used herein, an effective amount, i.e., the preferred range of barrier enhancing additive, is from 0.1% by wt. to 20% by wt. of the base polymer comprising the polymeric article.
Polymeric articles, and particularly extruded film or injection stretch blow molded polyester (e.g., PET) bottles, which contain one or more of the barrier-enhancing additives described herein, exhibit substantially reduced oxygen and carbon dioxide permeability values when measured according to ASTM D3985 and water vapor permeability values when measured according to ASTM F1249 in comparison to corresponding polymeric articles which contained no barrier-enhancing additives.
DETAILED DESCRIPTION OF THE INVENTION
The present invention resides in the discovery that oxygen, water vapor and carbon dioxide (CO2) permeability values for shaped polymeric containers and films can be substantially reduced by incorporating into the base polymer from which the articles are formed from about 0.1% by wt. up to about 20% by wt. of a barrier-enhancing additive of the type defined herein.
A uniform physical blend, or mixture, is prepared comprising the base polymer and one or more barrier-enhancing additives in the desired concentrations. As used herein with reference to the invention, the term "composition" is intended to mean a physical blend or mixture. Water-sensitive base polymers, such as, for

example, polyesters should preferably be thoroughly dried by heating under air or nitrogen flow or vacuum as known to those experienced in the art. The mixture is then heated and extruded or molded at a sufficiently high temperature to melt the base polymer and provide for sufficient mixing of the additive or mixture of additives within the base polymer matrix. By way of example using PET, such melt temperature ranges from about 255°C to 300°C. The composition thus produced comprises the barrier-enhancing additive (or mixture of such additives) substantially in its (their) original molecular form; that is, only small amounts of barrier-enhancing additive have been observed to react with the base polymer via trans-esterification or other reaction mechanism typical of the functional groups present. It is preferred to prepare and extrude or mold the polymer composition under conditions of relatively low temperature and processing residence time which thereby minimizes the opportunity for the barrier-enhancing additives to react with the base polymer. Best performance in terms of desirable mechanical properties of polymeric containers and films produced according to the invention is achieved when no more than about 10% of the gas barrier-enhancing additive has reacted with the base polymer. As a consequence of any reaction of a gas barrier-enhancing additive within the scope of the invention with a base polymer, the molecular weight of the starting base polymer may decrease.
The gas barrier-enhancing additives found to be most suitable for carrying out the invention are selected from the group consisting of:
(a) monoesters of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (A)

wherein R is C1 - C8 alkyl, benzyl, phenyl or naphthyl; Ar is substituted or unsubstituted phenylene or naphthylene; or formula (AA) where M is a cation such as, but not limited to, sodium, ammonium, tetraalkyl ammonium, potassium, calcium, magnesium or zinc;
(b) diesters of hydroxybenzoic acid of the formula (B)

wherein Ar is as defined above, and R1 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above.
(c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C)

wherein R and Ar are as defined above; or formula (CC) where M is as defined above.

(d) diamides of hydroxy benzoic acid of the formula (D)

wherein Ar is as defined above, and R2 is C1 - C8 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (DD) where M is as defined above.
(e) ester-amides of hydroxybenzoic acid of the formula (E)

where Ar is as defined above and R3 is C1 - C8 alkyl, C1 - C8 dialkyl, (CH2CH2O)k(CH2CH2, where k is 1 or greater, benzyl, phenyl or naphthyl, or formula (EE) where M is as defined above.
The above-defined barrier-enhancing additives can be obtained from commercial suppliers or they can be synthesized using established procedures.
Base polymers most suitable for use in practicing the invention comprise thermoplastic homopolymers, copolymers (both block and random), and blends of such thermoplastic polymers. Most suitable are polyester homopolymers and copolymers. Among suitable polyester base polymers are those polymers which contain structural units derived from one or more organic diacids (or their corresponding esters) selected from the group consisting of terephthalic acid,

isophthalic acid, naphthalene dicarboxylic acids, hydroxybenzoic acids, hydroxynaphthoic acids, cyclohexane dicarboxylic acids, succinic acid, glutaric acid, adipic acid, sebacic acid, 1,12-dodecane dioic acid and the derivatives thereof, such as, for example, the dimethyl, diethyl, or dipropyl esters or acid chlorides of the dicarboxylic acids and one or more diols selected from ethylene glycol, 1,3-propane diol, nathphalene glycol, 1,2-propanediol, 1,2-, 1,3-, and 1,4-cyclohexane dimethanol, diethylene glycol, hydroquinone, 1,3-butane diol, 1,5-pentane diol, 1,6-hexane diol, triethylene glycol, resorcinol, and longer chain diols and polyols which are the reaction products of diols or polyols with alkylene oxides.
In a preferred embodiment of the invention the polyester base polymer is polyethylene terephthalate (PET), which includes PET polymer which has been modified with from about 2 mole% up to about 5 mole% of isophthalate units. Such modified PET is known as "bottle grade" resin and is available commercially as Melinar® Laser+ polyethylene terephthalate brand resin (E. I. du Pont de Nemours and Company, Wilmington, DE). As used hereinafter in illustrating the invention, the term PET will refer to commercially available "bottle grade" polyester resin.
Preparation of Film and Container Samples
Film samples are indicative of the improved gas barrier properties obtainable from the invention. Such film samples were generated from physical blends of a base polymer and a selected additive from among those described herein, and the samples were either compression molded or extrusion cast using a co-rotating twin screw extruder with a slit die, typically having a 0.38 mm gap, a quench roll, and a vacuum port on the front barrel section, with barrel, adapter, and die temperatures set at 240°C to 275 °C depending on the polymer composition being used. Melt temperatures were measured with a thermocouple, and, for samples prepared using a twin screw extruder, melt temperatures were typically about 15°C to 20°C above the set temperature. In a few instances as noted, a transfer line, in which static mixers were installed within the line in place of a compounding screw, was used along with a slit die. Films were typically 0.05 to 0.25 mm thick. The thick films were subsequently stretched biaxially simultaneously to 3.5X by 3.5X using a Long stretcher at 90°C, 9000%/minute unless otherwise noted

For fabricating bottles, 26g preforms were injection molded using a Nissei ASB 50 single stage injection stretch blow molding machine with barrel temperatures set at about 265°C and with a total cycle time of about 30 seconds. The preforms were immediately blown into 500 mL round-bottomed bottles with a blow time of 5 seconds. All other pressure, time and temperature set-points were typical for commercially available PET bottle resin.
Tensile bars 1/8" thick were molded using a 6oz. injection molding machine with the following machine set-up: barrel temp: 255°C, mold temp: 20°C/20°C, cycle time: 20 sec/20 sec, injection pressure: 5.5 MPa, RAM speed: fast, screw speed: 60 rpm, and back pressure: 345 kPa.
Analytical Procedures
NMR Spectrometry
Samples for 1H NMR were dissolved in tetrachloroethane-d2 at 130°C. Spectra were acquired at 120°C at 500 MHz.
Thermal Analysis
Differential Scanning Calorimetric data were acquired at 2°/min on a T A Instruments calorimeter.
Permeability
Oxygen permeability values (OPV) were measured for each sample according to ASTM procedure D3985 at 30°C, 50% RH on an Ox-Tran 1000 instrument from Modern Controls, Inc. Carbon dioxide permeability was measured at 25 °C and 0% RH on a Permatran CIV instrument, also from Modern Controls, Inc. Water vapor permeability was measured at 37-38°C, 100% RH on a Permatran-W600 instrument, also from Modern Controls, according to ASTM procedure F1249.

Intrinsic Viscosity
Intrinsic viscosity values were determined from 0.4 wt% solution of polymers or polymer blends in a 1:1 (by weight) mixture of methylene chloride and trifluoroacetic acid at 20°C.
EXAMPLES
Example 1
Films comprising commercially available PET resin (Melinar® Laser+ PET brand resin) as the base polymer plus a barrier additive were prepared by a variety of methods as follows: melt pressing (M), extrusion compounding through a slit die (E), and transfer line mixing (T) into a slit die, and noted below in the table. Compositions are indicated in Table 1. After extrusion, films were simultaneously biaxially stretched to 3.5X by 3.5X at 90°C and at a rate of 9000%/min. Oxygen permeation values (OPV) were measured according to ASTM procedure D3985 at 30° C, 50% relative humidity. Weight percent of the additive in.the resin was assayed by NMR; where such analysis was not possible, nominal values (i.e., amounts initially mixed into the resin) are noted. In each case, both in unstretched and stretched films, the OPV was lower in films which contained a barrier-enhancing additive according to the invention than typical PET values (Control values, Table 1). OPV units are cc-mils/100 sq. in-24 hr-atm.

Table 1

Sample Preparation* Additive Wt% (NMR) OPV: Unstretched OPV: Stretched
Control E None 0 11.08** 7.23**
A M Methyl 4-hydroxybenzoate 2.48 7.07 3.48
B T Methyl 4-hydroxybenzoate 5.74 3.76 3.56
C T Methyl 4-hydroxybenzoate 3.49 7.14 3.69
D T Methyl 4-hydroxybenzoate 1.55 8.17 4.70
E T Methyl 4-hydroxybenzoate 0.66 5.91
F E Ethyl 4-hydroxybenzoate 3.71 5.42 4.14
G E n-Propyl 4-hydroxybenzoate 2.90 7.91 4.74
H E i-Propyl 4-hydroxybenzoate 6.00 (nominal) 4.01
I M Benzyl 4-hydroxybenzoate 5.88 (nominal) 8.87 3.99
J M Phenyl 4-hydroxybenzoate 5.55 (nominal) 7.71 3.82
K E Phenyl hydroxynaphthoate 5 (nominal) 8.49 4.47
* Preparation methods: E = extrusion compounded then extrusion through a slit die to make film; M = melt-pressed film; T = transfer line with static mixers then extrusion through a slit die to make film.
** For unstretched PET film, the control OPV is the mean of values for seven different samples, each run in duplicate; the standard deviation is 0.49. For stretched film, the control OPV is the mean of values for 27 different samples, each run in duplicate; the standard deviation is 0.41.
Example 2
Films prepared from commercially available PET resin (Melinar® Laser+ brand PET resin) which contained zero or nominally 2 wt% of the sodium salt of

methyl 4-hydroxybenzoate were extruded using a twin screw extruder. Oxygen permeability values were determined for both as-cast and biaxially stretched films, as in Ex. 1. Films were stretched to 3.5X by 3.5X at 9000%/min, 100°C. The OPV for the stretched film containing the additive was 5.18 cc-mils/100 sq. in-24 hr-atm stretched, versus 6.56 for stretched PET film without an additive; the additive therefore produced a 26.6% improvement in oxygen barrier performance.
Example 3
Poly(propylene terephthalate) ('3GT) films containing zero and nominally 3 wt% methyl 4-hydroxybenzoate ('MHB') were prepared using a twin screw extruder and a barrel setting of 240°C. Films containing no MHB and nominally 3 wt% MHB were stretched 3X by 3X at 55°C and 53 °C respectively. Oxygen permeability values for the 3GT films containing MHB were 4.72 cc-mil/100 sq. in-24 hr-atm for cast film and 3.59 cc-mil/100 sq. in-24 hr-atm for stretched film, versus the 3GT control OPV values of 8.56 for as-cast film and 5.30.for stretched film. Water vapor permeability at 38°C for as-cast films containing MHB was 2.22 g-mil/100 sq. in-24 hr and 1.95 g-mil/100 sq. in-24 hr for stretched film, versus the 3GT control values of 3.50 for as-cast film and 2.24 for stretched film.
Example 4
A blend of MHB with PET (IV 0.86) was prepared via twin-screw extrusion at 245°C. The resulting blend, which was a concentrate, had an IV of 0.86 dL/g, and contained 6.9% MHB by NMR analysis. The blend was dried overnight at 100°C under vacuum and combined with standard commercial PET bottle resin (IV 0.83 dL/g, dried 6 hours at 150°C). 26g sample preforms were then injection molded using a Nissei ASB 50 single stage injection stretch blow molding machine, using barrel temperatures of about 265°C and a total cycle time of approximately 30 seconds. The preforms were immediately blown into 500 mL round-bottomed bottles with a blow time of 5 seconds. All other pressure, time and temperature set-points were typical for standard PET bottle resin. A control set of bottles made only

of the standard PET bottle resin (IV 0.83, dried 6 hours at 150°C) was prepared under the same conditions. The oxygen permeation value for panels cut from bottles containing 1.97 wt% methyl 4-hydroxybenzoate ('MHB') was determined to be 3.69 cc-mils/100 sq. in-24 hr-atm versus 5.73 for a control PET bottle panel. Carbon dioxide permeation values were 9.65 cc-mil/100 sq. in-24 hr-atm. for the bottle with MHB and 14.62 for the control panel.
Example 5 Commercially available PET film containing 4 wt% MXD-6 6007 nylon (Mitsubishi Gas Chemical Corp.) and, nominally, 3 wt% MHB was extruded along with a PET control film. The films were biaxially stretched 3.5X by 3.5X as in Example 1. The OPV for the film containing the additives was 2.59 cc-mils/100 sq. in-24 hr-atm, versus the control film's OPV of 7.14.
Example 6
A diester of p-hydroxybenzoic acid ('HBA') (corresponding to Formula B where R1 = CH2CH2) was synthesized from the reaction of stoichiometric mixtures of HBA and ethylene glycol in diphenyl ether with the catalyst butyl stannoic acid. PET films containing 0 and 4.55 wt% of this diester were extruded and then stretched as in Example 1. The OPV of the film containing the diester was 3.93 cc-mils/100 sq. in-24 hr-atm, and the OPV of the PET film without the diester was 7.32 cc-mils/100 sq. in-24 hr-atm.
Example 7 The benzamide of HBA (corresponding to Formula C where R = phenyl) was synthesized from the reaction of MHB with benzylamine. An extruded PET film containing a nominal 3 wt% of this benzamide and stretched as in Example 1 exhibited an OPV of 5.00 cc-mil/100 sq. in-24 hr-atm, vs. a PET control film which had an OPV of 6.94.

Example 8
The diamide of HBA (corresponding to Formula D where R1 = CH2CH2) was synthesized from the reaction of 4-acetoxybenzoyl chloride with ethylene diamine, followed by basic hydrolysis of the acetate groups. An extruded PET film containing a nominal 3 wt% of this diamide and stretched as in Example 1 exhibited an OPV of 5.46 cc-mil/100 sq. in-24 hr-atm whereas a PET control film exhibited an OPV of 7.79.
Example 9
A diester of HBA and triethylene glycol was synthesized from the reaction of stoichiometric mixtures of HBA and triethylene glycol in diphenyl ether with the catalyst butyl stannoic acid. PET film containing 6.49 wt% of this diester (determined by NMR) was extruded and stretched as in Example 1. The OPV for this film was 4.0 cc-mil/100 sq. in-24 hr-atm whereas a PET control film exhibited an OPV of 7.04.
Example 10
A blend of 97 wt% dried PET resin (Melinar® Laser+ brand PET resin) and 3 wt% methyl 4-hydroxybenzoate was mixed thoroughly and added to the hopper of a 6 oz. injection molding machine. Standard 1/8" thick tensile bars were molded with the following machine set-up: barrel temp 255°C, mold temp: 20°C/20°C, cycle time: 20 sec/20 sec, injection pressure: 5.5 MPa, RAM speed: FAST, screw speed: 60 rpm, and back pressure: 345 kPa. Intrinsic viscosity was measured on sections which were cut from the center of the bars using a 0.4% solution in 1:1 TFA: CH2Cl2 at 19°C. The I.V. was 0.73 dL/g vs. a control PET resin sample molded under identical conditions which had an I.V. of 0.73 dL/g.
In contrast, the I.V. of the bottle from Example 4, containing 1.97 wt% MHB and prepared from a pre-compounded MHB/PET concentrate, was 0.464 dL/g, and the control PET bottle I.V. was 0.76 dL/g. This example demonstrates that degradation of the polymer composition's molecular weight (as evidenced by I.V.) can be avoided by selection of appropriate processing conditions.

Example 11
Laser+ PET films containing 0 to 3.46 wt% MHB were prepared by extrusion compounding. Two of these were also biaxially stretched as in Example 1. Water vapor permeabilities (g-mil/100 sq. in - 24 hr) at 38°C, 100% relative humidity are tabulated below.

MHB Content (wt%) Water Vapor Permeability, As-Cast Film Water Vapor Permeability, Stretched Film
0 4.31 2.43
0.56 3.87 —
1.91 3.42 1.69
3.46 2.93 —
Example 12
Films of Lexan® 134r polycarbonate, Ultem® 1000 polyetherimide (both manufactured by General Electric), and Radel® polyethersulfone (manufactured by Boedeker Plastics, Inc.) containing 0 or nominally 5 wt% n-propyl p-hydroxybenzoate (PUB) were melt-pressed at 260,270, and 270°C, respectively. Oxygen permeabilities (OPV) at 30°C are tabulated below.

Polymer OPV, no PHB (cc-mil/100sq. in. 24 hr) OPV,nom.5 wt% PHB (cc-mil/100 sq. in. 24hr)
Lexan® 134r polycarbonate 232.5 138.7
Ultem® 1000 polyetherimide 48.05 24.45
Radel® polyethersulfone 89.79 52.11

Example 13
Films of a copolymer of composition 7.4% poly(isosorbide terephthalate)-co-92.6% poly(ethylene terephthalate), prepared according to U.S. Patent No. 5,959,066, containing 0 to 3.85 wt% MHB were prepared by extrusion compounding, then biaxially stretched 3.5X by 3.5X at 90°C (95°C for 0% MHB), 9000%/min. Oxygen permeabilities are tabulated below.

MHB Wt% OPV (cc-mil/100 sq. in/24 hr-atm)
0 8.22
0.70 8.02
2.24 5.57
3.85 3.98

We Claim:
1. A method for reducing gas permeability of shaped thermoplastic polymeric articles wherein the polymer from which the article is formed in selected from the group consisting of polyesters, polycarbonates, polyetherimides and polyethersulfones and wherein the method comprises the steps of (1) incorporating into the polymer an amount of a of a barrier-enhancing additive or a mixture of barrier-enhancing additives effective to reduce gas permeability and selected from the group consisting of:
(a) monoesters of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (A)

wherein R is C1 - C4 alkyl, benzyl, phenyl or naphthyl; Ar is substituted
or unsubstituted phenylene or naphthylene; or formula (AA) where M is
a cation such as, but not limited to, sodium, ammonium, tetraalkyl
ammonium, potassium, calcium, magnesium or zinc;

(b) diesters of hydroxybenzoic acid of the formula (B)

wherein Ar is as defined above, and R1 is C1-C4 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above.
(c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C)

wherein R and Ar are as defined above; or formula (CC) where M is as defined above.

(b) diesters of hydroxybenzoic acid of the formula (B)

wherein Ar is as defined above, and R1 is C1-C4 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (BB) where M is as defined above.
(c) monoamides of hydroxybenzoic acid and hydroxynaphthoic acid of the formula (C)

wherein R and Ar are as defined above; or formula (CC) where M is as defined above.

(d) diamides of hydroxybenzoic acid of the formula (D)

wherein Ar is as defined above, and R2 is C1 - C4 alkyl, (CH2CH2O)kCH2CH2 where k is 1 or more, benzyl, phenyl or naphthyl; or formula (DD) where M is as defined above.
(e) ester-amides of hydroxybenzoic acid of the formula (E)

where Ar is as defined above and R3 is C1 - C4 alkyl, C1 - C8 dialkyl, (CH2CH2O)kCH2CH2 where k is 1 or greater, benzyl, phenyl or naphthyl, or formula (EE) where M is as defined above by first forming a physical mixture comprising the polymer and one or more of the gas barrier

enhancing additives, (2) heating the mixture to a temperature sufficiently high to melt the polymer but low enough to maintain the one or more gas barrier enhancing additives substantially in its or their original molecular form, and (3) forming the article.
2. The method as claimed in Claim 1, wherein the barrier-enhancing additive or mixture of barrier-enhancing additives is incorporated into the polymer by physically mixing the components together and then extruding the resulting mixture through an extruder whereby the total concentration of barrier-enhancing additive in the extruded composition is from 0.1% by wt. up to 20% by wt. of the composition.
3. The method as claimed in Claim 2, wherein the polymer comprising the container, sheet or film is selected from thermoplastic homopolymers, random or block copolymers and a blend or blends of such homopolymers and copolymers.
4. The method as claimed in Claim 3, wherein the thermoplastic homopolymer or random or block copolymer is a polyester homopolymer or copolymer.
Dated this 11th day of January, 2002
[RANJNA MEHTA-DUTT]
OF REMFRY & SAGAR
ATTORNEY FOR THE APPLICANTS

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Patent Number

215212

Indian Patent Application Number

IN/PCT/2002/00039/MUM

PG Journal Number

13/2008

Publication Date

31-Mar-2008

Grant Date

22-Feb-2008

Date of Filing

11-Jan-2002

Name of Patentee

E.I. DU PONT DE NEMOURS AND COMPANY

Applicant Address

1007 MARKET STREET, WILMINGTON, DELAWARE 19898, USA

Inventors:

#	Inventor's Name	Inventor's Address
1	IRENE GREENWALD PLOTZKER	2307 WYNWOOD DRIVE, WILMINGTON, DELAWARE 19810, USA
2	SAMUEL TACITUS D'ARCANGELIS	2522 TRAYNOR AVENUE, CLAYMONT, DELAWARE 19703, USA.
3	THOMAS FORD	3122 CENTERVILLE ROAD, GREENVILLE, DELAWARE 19807, USA
4	KENNETH GEORGE SHARP	164 HAMILTON ROAD, LANDENBERG, PENNSYLVANIA 19350, USA.

PCT International Classification Number

B65D 65/38

PCT International Application Number

PCT/US00/21777

PCT International Filing date

2000-08-10

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	09/634,288	2000-08-09	U.S.A.
2	60/148,537	1999-08-12	U.S.A.