POLYAMIDE RESIN COMPOSITION

Abstract

The present invention relates to a polyamide resin composition comprising polyamide (X) comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and an alkali compound (A), wherein the following equations (1) to (3) are satisfied: 0.03≦P<0.32  (1) 2.2≦M<26.1  (2) 5<M/P≦200  (3) wherein P represents a mole concentration (μmol/g) of a phosphorus atom contained per g of the polyamide resin composition; and M represents a sum (μmol/g) of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide resin composition by valencies thereof respectively.

Description

TECHNICAL FIELD

The present invention relates to a polyamide resin composition, specifically to a polyamide resin composition which is industrially useful as a packaging material and a material for fibers.

BACKGROUND ART

Polyamide having a metaxylylene group in a polymer principal chain has a high rigidity and is widely used as a molding material, and in addition thereto, it is excellent as well in a performance of cutting off oxygen, carbon dioxide and the like and is also used as a gas-barrier material for various packaging materials such as bottles, sheets, films and the like. Particularly in polyamide used for applications such as bottles, sheets, films, fibers and the like, attentions are paid to mixing of foreign matters. Due to that the molded and processed products are transparent and thin, that a high level and delicate mold processing technology is required and that foreign matters are very highly likely to damage the performances of the molded and processed products, mixing of foreign matters brings about the inferior appearance, an increase in a rate of generating defects such as breaking and the like attributable to foreign matter-generating sites and a reduction in the productivity.

Foreign matters originating in polyamide include powders called a fine, thin films called a froth, yellowed matters and carbides produced by thermal degradation and gelatinous matters. It is the best countermeasure to inhibit the above foreign matters from being produced, but when they are inevitably produced, they have to be separated and removed from the pelletized products. The powders and the thin films are usually removed by wind selection, and the yellowed matters and the carbides can be removed by a screening equipment using an optical sensor. Various separating equipments are commercially available, and the sure removing effects can be expected.

On the other hand, gels are estimated to be produced due to that the molecules are damaged (the polymer molecules are degraded by radicals generated) during polymerization and mold processing to bring about abnormal reactions (turned into three-dimensional polymers) such as growing of non-linear molecules and the like and that they are turned into an extremely high molecular weight as compared with those of other polyamide molecules. Accordingly, a thermal history has to be reduced to the utmost in the production step in order to obtain polyamide containing less gel, and measurements such as setting a balance of terminal group concentrations and adding a heat stabilizer or an antioxidant are carried out. However, some of the above additives show a catalytic effect to amidation reaction, and on the contrary, they expedite excessively polymerization reaction to bring about an increase in gels in a certain case. Accordingly, the reaction is carried out usually while maintaining a balance between promotion and inhibition of the reaction by adding a specific amount of an alkali compound having further a reaction inhibitory effect.

Gels produced in a melt polymerization step can be removed by a filter and the like, but the gels are turned into fine particles by a flow pressure and pass through the filter in many cases. Further, gels are likely to be produced as well in solid phase polymerization carried out in producing high viscosity products, and therefore it is almost impossible to completely remove them.

Further, gels can be produced as well in melting in mold processing other than during production of polyamide. Even when used is polyamide in which a marked difference in a production amount of gels is not observed in evaluating a quality of the polyamide after production thereof, the difference is exerted in a certain case in mold processing, and a cause thereof is estimated to be attributable to that an excessive thermal history is applied to a part of the polymer in staying parts thereof such as screw grooves, a filter, a die and the like in mold processing. Further, if a polyamide resin stays in an inside of a molding machine for a long time in molding a bottle, a degraded matter of the resin is turned into burnt deposits, and they are mixed in the product to deteriorate a yield of the product, or the burnt deposits clog flow channels in an inside of the molding machine to make it impossible to carry out the molding in a certain case. When burnt deposits are generated, it is necessary to use a purging agent or to disassemble and clean the die, and the stable production is prevented. It can be found from the above matters that it is important for obtaining finally mold processed articles having less gel and burnt deposit to produce polyamide having further less gel and a higher grade and design a mold processing apparatus having very small staying parts.

It is necessary for producing polyamide having further less gel to inhibit a thermal history in the production, set a balance between an effective concentration of a terminal group and an amount of a stabilizer and remove produced gels as well in melt polymerization and solid phase polymerization, but the effects thereof have been limited. Further, in designing a mold processing apparatus, it is possible to reduce production of gels by subjecting, for example, metal parts which are brought into contact with the resin to plating treatment, but it is difficult in terms of constitution of the apparatus to completely eliminate the staying parts. Further, the respective molding apparatuses have to be subjected to the treatment, and it is lacking in the possibility thereof in terms of the versatility and the cost. Particularly in polyamide comprising a diamine component in which xylylenediamine is a principal component, radicals are liable to be produced in a benzylmethylene site of xylylenediamine, and production of gels provides more serious problems than in other polyamides.

Patent document 1 discloses a method in which at least one selected from a lubricant, an organic phosphorus base stabilizer, a hindered phenol compound and a hindered amine compound is added in an amount of 0.0005 to 0.5 parts by mass in mold processing of polyamide to thereby inhibit gels from being produced.

Patent document 2 discloses a method in which fish eyes are inhibited from being produced in mold processing by adding 0.001 to 0.015 parts by mass of a metal salt of a higher fatty acid and a polyhydric alcohol compound in order to enhance a lubricity of polyamide to inhibit shearing heat from being generated in the mold processing.

Patent document 3 discloses a method in which 50 to 1,000 ppm by weight of a phosphinic acid compound or a phosphonous acid compound and 1 to 5 mole times of an alkali compound based on a concentration of phosphorus atoms contained are added to thereby inhibit gels from being produced.

Patent documents 4 and 5 disclose methods in which a phosphorus base compound and an alkali metal salt are added in a fixed balance to thereby inhibit a back pressure of a filter from being elevated by a phosphorus-modified product and inhibit gels from being produced.

Patent documents 6 and 7 disclose methods in which the amounts of pyrophosphoric acid and other phosphorus base compounds contained in polyamide are controlled to thereby inhibit a back pressure of a filter from being elevated by a phosphorus-modified product and inhibit gels from being produced.

CITATION LIST

Patent Documents

• [Patent document 1] JP-A-2001-164109
• [Patent document 2] JP-B-3808847
• [Patent document 3] JP-A-49-38950
• [Patent document 4] JP-A-2005-194328
• [Patent document 5] JP-A-2005-194330
• [Patent document 6] JP-A-2007-92053
• [Patent document 7] JP-A-2007-92054

SUMMARY OF INVENTION

Technical Problem

However, the method described in Patent document 1 is short of effects when the results described in the examples are observed in terms of a practical aspect, and specific grounds for inhibiting gels from being produced in the respective additives are scarcely referred to. Further, it is not at all described in Patent document 2 that a change itself in a quality of polyamide is inhibited. A method for determining a gel production amount in Patent document 3 is unsatisfactory in imitation of an actual mold processing environment, and in fact, production of gels can not be sufficiently inhibited by the method described in Patent document 3. In Patent documents 4 to 7, the phosphorus base compound and the alkali metal salt are described within the limit of adding them in the melt polymerization, and production of gels in mold processing can not be sufficiently inhibited by these methods. Furthermore, some methods in which gels or fish eyes are inhibited from being produced in mold processing have been studied from viewpoint of a material, but a useful method in which burnt deposits are inhibited from being produced in molding a bottle have not been discovered.

A problem to be solved by the present invention is to provide a polyamide resin composition which has a good color tone and which produces less gel and burnt deposit in mold processing, a production process for the same, and a multilayer molded article prepared by using the above polyamide resin composition.

Solution to Problem

The present invention provides a polyamide resin composition, a production process for the same, a polyamide master batch and a multilayer molded article each shown below.

[1] A polyamide resin composition comprising polyamide (X) comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and an alkali compound (A), wherein the following equations (1) to (3) are satisfied:

0.03≦P<0.32  (1)

2.2≦M≦26.1  (2)

5<M/P≦200  (3)

wherein P represents a mole concentration (μmol/g) of a phosphorus atom contained per g of the polyamide resin composition; and M represents a sum (μmol/g) of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide resin composition by valencies thereof respectively.
[2] A production process for the polyamide resin composition according to the above item [1], comprising:

(a) a step in which diamine containing 70 mol % or more of metaxylylenediamine and dicarboxylic acid are subjected to polycondensation under the presence of a phosphorus atom-containing compound (B) to obtain polyamide (X) and

(b) a step in which an alkali compound (A) is added to the polyamide (X) obtained in the step (a) described above.

[3] A polyamide master batch used for the production process for the polyamide resin composition according to the above item [2],

wherein the polyamide master batch is obtained in a step in which 90 to 99 parts by mass of polyamide (X) comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and 10 to 1 parts by mass of an alkali compound (A) are molten and kneaded under the presence of a phosphorus atom-containing compound (B) and an alkali metal compound (C),

wherein the polyamide master batch satisfies that a sum of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the master batch by valencies thereof respectively is 12 μmol/g or more and 900 μmol/g or less, and the alkali compound (A) satisfies the following conditions (i) and (ii):

(i) it is a carbonate, a hydrogencarbonate or a carboxylate having 10 or less carbon atoms of an alkali metal or an alkaline earth metal and

(ii) a melting temperature Tm of the alkali compound (A) is not higher than a melt-kneading temperature K.

[4] A multilayer molded article comprising an outermost layer, an innermost layer and at least one gas-barrier layer between the outermost layer and the innermost layer, wherein the outermost layer and the innermost layer are constituted from a polyester resin comprising a dicarboxylic acid unit containing 80 mol % or more of a terephthalic acid unit and a diol unit containing 80 mol % or more of an ethylene glycol unit, and the gas-barrier layer is constituted from the polyamide resin composition according to the above item [1].

Advantageous Effects of Invention

According to the present invention, a polyamide resin composition which has a good color tone and which produces less gel in production and mold processing can be provided. Further, the multilayer molded article of the present invention contains less burnt deposit and has a very high industrial value as a multilayer bottle and the like.

DESCRIPTION OF EMBODIMENTS

[Polyamide Resin Composition]

The polyamide resin composition of the present invention comprises polyamide (X) comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and an alkali compound (A), wherein the following equations (1) to (3) are satisfied:

0.03≦P<0.32  (1)

2.2≦M≦26.1  (2)

5<M/P≦200  (3)

wherein P represents a mole concentration (μmol/g) of a phosphorus atom contained per g of the polyamide resin composition; and M represents a sum (μmol/g) of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide resin composition by valencies thereof respectively.

The alkali compound is used, as described above, as a neutralizing agent for the phosphorus base compound added in the polymerization. However, a use amount thereof in the polymerization of the polyamide is limited from the viewpoint of a balance with the phosphorus base compound. The inventors of the present invention have made earnest studies, and as a result, found that gels can be inhibited from being produced in mold processing by adding the alkali compound in the mold processing after polymerizing the polyamide to elevate a concentration thereof; an amount of gels produced is small even if a staying situation of the molten polyamide continues over a long period of time; and the resulting molded article is decreased in gels and coloring and has a good appearance. The present invention has been completed based on the above findings.

<Polyamide (X)>

The diamine unit constituting the polyamide (X) contains 70 mol % or more, preferably 80 mol % or more and more preferably 90 mol % or more of the metaxylylenediamine unit. If the metaxylylenediamine unit in the diamine unit accounts for 70 mol % or more, the polyamide (X) can exert an excellent gas-barrier property. Further, the polyamide (X) exerts characteristics excellent in a co-injection moldability and a co-stretching blow moldability with a polyester resin (principally polyethylene terephthalate) and is provided with a good formability.

Capable of being shown as the examples of compounds other than the metaxylylenediamine unit which can constitute the diamine are aliphatic diamines such as tetramethylenediamine, pentamethylenediamine, 2-methylpentanediamine, hexamethylenediamine, heptamethylenediamine, octamethylenediamine, nonamethylenediamine, decamethylenediamine, dodecamethylenediamine, 2,2,4-trimethyl-hexamethylenediamine, 2,4,4-trimethyl-hexamethylenediamine and the like; alicyclic diamines such as 1,3-bis(aminomethyl)cyclohexane, 1,4-bis(aminomethyl)cyclohexane, 1,3-diaminocyclohexane, 1,4-diaminocyclohexane, bis(4-aminocyclohexyl)methane, 2,2-bis(4-aminocyclohexyl)propane, bis(aminomethyl)decalin, bis(aminomethyl)tricyclodecane and the like; and diamines having aromatic rings, such as bis(4-aminophenyl)ether, paraphenylenediamine, paraxylylenediamine, bis(aminomethyl)naphthalene and the like. However, they shall not be restricted to the above compounds.

Capable of being shown as the examples of compounds which can constitute the dicarboxylic acid unit constituting the polyamide (X) are aliphatic dicarboxylic acids such as succinic acid, glutaric acid, pimelic acid, adipic acid, suberic acid, azelaic acid, sebacic acid, undecanedioic acid, dodecanedioic acid, dimer acid and the like; alicyclic dicarboxylic acids such as 1,4-cyclohexanedicarboxylic acid and the like; and aromatic dicarboxylic acids such as terephthalic acid, isophthalic acid, orthophthalic acid, xylylenedicarboxylic acid, naphthalenedicarboxylic acid and the like. However, they shall not be restricted to the above compounds. Among them, adipic acid and sebacic acid are preferred.

Polyamide comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit containing 70 mol % or more, preferably 80 mol % or more and more preferably 90 mol % or more of an adipic acid unit can be shown as the example of the polyamide (X) which can be preferably used in the present invention. If 70 mol % or more of the adipic acid is contained in the dicarboxylic acid unit, a reduction in the gas-barrier property and an excessive reduction in the crystallinity can be avoided. At least one of α,ω-linear aliphatic dicarboxylic acids having 4 to 20 carbon atoms is preferably used as a compound which can constitute the dicarboxylic acid unit other than the adipic acid unit.

Further, polyamide comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit containing 70 to 99 mol % of an adipic acid unit and 1 to 30 mol % of an isophthalic acid unit can also be shown as the example of the polyamide (X) which can be preferably used in the present invention. Addition of the isophthalic acid unit as the dicarboxylic acid unit makes it possible to reduce the melting point and lower the mold processing temperature and therefore makes it possible to reduce a thermal history during molding the polyamide resin composition and inhibit gels and burnt deposits from being produced.

Further, polyamide comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit containing 70 mol % or more, preferably 80 mol % or more and more preferably 90 mol % or more of a sebacic acid unit can also be shown as the example of the polyamide (X) which can be preferably used in the present invention. If 70 mol % or more of the sebacic acid unit is contained in the dicarboxylic acid unit, a reduction in the gas-barrier property and an excessive reduction in the crystallinity can be avoided. In addition thereto, the melting point can be reduced, and the mold processing temperature can be lowered. Further, gels and burnt deposits can be inhibited from being produced. At least one of α,ω-linear aliphatic dicarboxylic acids having 4 to 20 carbon atoms is preferably used as a compound other than the sebacic acid unit which can constitute the dicarboxylic acid unit.

In addition to the diamines and the dicarboxylic acids each described above, lactams such as ε-caprolactam, laurolactam and the like, aliphatic aminocarboxylic acids such as aminocaproic acid, aminoundecanoic acid and the like and aromatic aminocarboxylic acids such as p-aminomethylbenzoic acid and the like can also be used as a copolymerization component for a component constituting the polyamide (X) as long as the effects of the present invention are not damaged.

From viewpoint of moldability in molding of multilayer molded articles, a number average molecular weight of the polyamide (X) is preferably 10,000 to 50,000, more preferably 15,000 to 45,000 and further preferably 20,000 to 40,000, and it is suitably selected according to the uses and the molding method of the polyamide resin composition. In a case where the fluidity of some extent is required in the production, for example, a case of the use such as a film and the like, a number average molecular weight of the polyamide (X) is preferably 20,000 to 30,000. In a case where the melt strength is required in the production, for example, a case of the use such as a sheet and the like, a number average molecular weight of the polyamide (X) is preferably 30,000 to 40,000.

A number average molecular weight of the polyamide (X) is calculated from the following equation (4):

Number average molecular weight=2×1,000,000/([COOH]+[NH₂])  (4)

wherein [COOH] represents a concentration (μmol/g) of a terminal carboxyl group in the polyamide (X), and [NH₂] represents a concentration (μmol/g) of a terminal amino group in the polyamide (X).

In the present invention, a value calculated by dissolving the polyamide in a phenol/ethanol mixed solvent and neutralizing and titrating the resulting solution with a diluted hydrochloric acid aqueous solution is used for the terminal amino group concentration, and a value calculated by dissolving the polyamide in benzyl alcohol and neutralizing and titrating the resulting solution with a sodium hydroxide aqueous solution is used for the terminal carboxyl group concentration.

<Alkali Compound (A)>

The polyamide resin composition of the present invention contains the alkali compound (A) from the viewpoint of preventing gels and burnt deposits from being produced in the mold processing.

The preferred specific examples of the alkali compound (A) used in the present invention include hydroxides, hydrides, alkoxides, carbonates, hydrogencarbonates and carboxylates of alkali metals and alkaline earth metals, but they shall not specifically be restricted to the above compounds. The preferred specific examples of the alkali metals and the alkaline earth metals include sodium, potassium, lithium, rubidium, cesium, magnesium, calcium and the like.

The hydroxides of the alkali metals and the alkaline earth metals include, for example, lithium hydroxide, sodium hydroxide, potassium hydroxide, rubidium hydroxide, cesium hydroxide, magnesium hydroxide, calcium hydroxide and the like.

The hydrides of the alkali metals and the alkaline earth metals include, for example, lithium hydride, sodium hydride, potassium hydride and the like.

The alkali metal alkoxides and the alkaline earth metal alkoxides are preferably alkoxides having 1 to 4 carbon atoms and include, for example, sodium methoxide, potassium methoxide, lithium methoxide, magnesium methoxide, calcium methoxide, sodium ethoxide, potassium ethoxide, lithium ethoxide, magnesium ethoxide, calcium ethoxide, sodium t-butoxide, potassium t-butoxide, lithium t-butoxide, magnesium t-butoxide, calcium t-butoxide and the like.

The carbonates and the hydrogencarbonates of the alkali metals and the alkaline earth metals include, for example, sodium carbonate, sodium bicarbonate, potassium carbonate, potassium bicarbonate, lithium carbonate, calcium carbonate, magnesium carbonate, sodium hydrogencarbonate, calcium hydrogencarbonate and the like, and anhydrous salts and hydrate salts thereof can be used.

The carboxylates of the alkali metals and the alkaline earth metals are preferably carboxylates having 1 to 10 carbon atoms, and anhydrous salts and hydrate salts thereof can be used. The specific examples of the carboxylic acids include, for example, linear saturated fatty acids such as formic acid, acetic acid, propionic acid, butyric acid, valeric acid, caproic acid, enanthic acid, capric acid, pelargonic acid, lauric acid, myristic acid, palmitic acid, stearic acid, eicosanoic acid, behenic acid, montanic acid, triacontanoic acid and the like; fatty acid derivatives such as 12-hydroxystearic acid and the like; aliphatic dicarboxylic acids such as oxalic acid, fumaric acid, maleic acid, succinic acid, glutaric acid, adipic acid, pimelic acid, suberic acid, azelaic acid, sebacic acid, undecanedioic acid, dodecanedioic acid and the like; hydroxy acids such as glycolic acid, lactic acid, hydroxybutyric acid, tartaric acid, malic acid, citric acid, isocitric acid, mevalonic acid and the like; and aromatic carboxylic acids such as benzoic acid, terephthalic acid, isophthalic acid, orthophthalic acid, pyromellitic acid, trimellitic acid, xylylenedicarboxylic acid, naphthalenedicarboxylic acid and the like.

The alkali compound (A) used in the present invention may be used in a single kind of the compounds described above or in combination of two or more kinds thereof. Among the compounds described above, carboxylates having 10 or less carbon atoms of the alkali metal are preferred from the viewpoints of a dispersibility in the polyamide (X) and an effect of inhibiting gels and burnt deposits from being produced, and sodium acetate and sodium acetate trihydrate are more preferred from the viewpoints of an economical efficiency and an effect of inhibiting gels and burnt deposits from being produced.

<Phosphorus Atom-Containing Compound (B)>

The phosphorus atom-containing compound (B) is used in the production of the polyamide (X) from the viewpoints of enhancing the processing stability in the melt processing and preventing the polyamide (X) from being colored. Accordingly, a phosphorus component is contained in the polyamide resin composition of the present invention.

The preferred specific examples of the phosphorus atom-containing compound (B) include hypophosphorous acid compounds (called as well phosphinic acid compounds or phosphinous acid compounds), phosphorous acid compounds (called as well phosphonic acid compounds) and the like, but they shall not specifically be restricted to the above compounds. The phosphorus atom-containing compound (B) may be metal salts or alkali metal salts.

The specific examples of the hypophosphorous acid compounds include hypophosphorous acid; hypophosphorous acid metal salts such as sodium hypophosphite, potassium hypophosphite, lithium hypophosphite and the like; hypophosphorous acid compounds such as ethyl hypophosphite, dimethyl phosphinate, phenyl methyl phosphinate, phenyl phosphinate, ethyl phenylphosphinate and the like; phenylphosphinous acid metal salts such as sodium phenylphosphinate, potassium phenylphosphinate, lithium phenylphosphinate and the like.

The specific examples of the phosphorous acid compounds include phosphorous acid and pyrophosphoric acid; phosphorous acid metal salts such as sodium hydrogenphosphite, sodium phosphite and the like; phosphorous acid compounds such as triethyl phosphite, triphenyl phosphite, ethylphosphonic acid, phenylphosphonic acid, diethyl phenylphosphonate and the like; phenylphosphonic acid metal salts such as sodium ethylphosphonate, potassium ethylphosphonate, sodium phenylphosphonate, potassium phenylphosphonate, lithium phenylphosphonate and the like.

The phosphorus atom-containing compound (B) may be used in a single kind of the compounds described above or in combination of two or more kinds thereof. Among the compounds described above, hypophosphorous acid metal salts such as sodium hypophosphite, potassium hypophosphite, lithium hypophosphite and the like are preferred from the viewpoints of an effect of accelerating the polymerization reaction of the polyamide (X) and an effect of preventing the coloring, and sodium hypophosphite is more preferred.

<Mole Concentrations of Phosphorus Atom, Alkali Metal Atom and Alkaline Earth Metal Atom>

A mole concentration P of a phosphorus atom contained per g of the polyamide resin composition of the present invention is 0.03 μmol/g or more and less than 0.32 μmol/g, preferably 0.06 to 0.26 μmol/g and more preferably 0.1 to 0.2 μmol/g from the viewpoints of enhancing the processing stability in the melt molding and preventing the polyamide from being colored. If P is less than 0.03 μmol/g, the polyamide is liable to be colored during polymerization, and gels and burnt deposits tend to be produced in the mold processing. Also, if P is too high, the polyamide is observed to be improved in coloring, but gels and burnt deposits are generated in the mold processing, and the back pressure is elevated in the mold processing in a certain case by clogging of a filter which is considered to be attributable to a thermally modified product of the phosphorus atom-containing compound (B).

A sum (hereinafter referred to as “a total mole concentration of an alkali metal atom and an alkaline earth metal atom”) M of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide resin composition of the present invention by valencies thereof respectively is 2.2 to 26.1 μmol/g, preferably 4.3 to 19.5 μmol/g and more preferably 6.5 to 13.0 μmol/g from the viewpoint of preventing gelation from being brought about in the melt processing.

It is estimated that controlling M to 2.2 μmol/g or more makes it possible to retard an increase in a molecular weight of the polyamide which is brought about by heating when the polyamide is molten to inhibit gels and burnt deposits from being produced. On the other hand, if M exceeds 26.1 μmol/g, inferior molding is caused in a certain case by a reduction in the viscosity. In addition thereto, coloring and whitening are brought about, and the alkali compound (A) is deposited in a certain case.

As described above, the alkali metal salt is used as the phosphorus atom-containing compound (B) in a certain case. Further, as described later, in the production of the polyamide resin composition of the present invention, the alkali metal compound (C) is added, if necessary, in the polycondensation of the polyamide, and the alkali compound (A) is added after the polycondensation of the polyamide. Accordingly, M is a sum (μmol/g) of values obtained by multiplying the mole concentrations of all of alkali metal atoms and alkaline earth metal atoms each contained per g of the polyamide resin composition by valencies thereof respectively.

In the present invention, a value (M/P) obtained by dividing a total mole concentration M of an alkali metal atom and an alkaline earth metal atom each contained per g of the polyamide resin composition of the present invention by a mole concentration P of a phosphorus atom contained per g of the polyamide resin composition of the present invention is in excess of 5 and 200 or less, preferably 20 to 150 and more preferably 35 to 100 from the viewpoints of preventing production of gels and burnt deposits which is brought about in the mold processing, enhancing the processing stability in the melt molding and preventing the polyamide from being colored. If M/P is 5 or less, an effect of inhibiting the amidation reaction by the alkali compound (A) is short in a certain case, and gels and burnt deposits are generated in the mold processing in some cases. On the other hand, if M/P exceeds 200, inferior molding is caused in a certain case by a reduction in the viscosity. In addition thereto, coloring and whitening are brought about in some cases, and the alkali compound (A) is deposited in a certain case.

[Production Process of Polyamide Resin Composition]

The polyamide resin composition of the present invention can be produced by a process comprising the following steps (a) and (b):

Step (a): a step in which diamine containing 70 mol % or more of metaxylylenediamine and dicarboxylic acid are subjected to polycondensation under the presence of the phosphorus atom-containing compound (B) to obtain the polyamide (X); and

Step (b): a step in which the alkali compound (A) is added to the polyamide (X) obtained in the step (a) described above.

<Step (a)>

The step (a) is a step in which diamine containing 70 mol % or more of metaxylylenediamine and dicarboxylic acid are subjected to polycondensation under the presence of the phosphorus atom-containing compound (B) to obtain the polyamide (X). Obtaining the polyamide (X) carrying out the polycondensation under the presence of the phosphorus atom-containing compound (B) makes it possible to enhance the processing stability in the melt molding and prevent the polyamide (X) from being colored.

A use amount of the phosphorus atom-containing compound (B) is an amount in which a mole concentration P of a phosphorus atom contained per g of the polyamide resin composition falls in the range described above.

The production process for the polyamide (X) shall not specifically be restricted as long as it is carried out under the presence of the phosphorus atom-containing compound (B), and it can be carried out by an optional method on optional polymerization conditions. The polyamide (X) can be produced, for example, by heating a nylon salt comprising a diamine component (for example, metaxylylenediamine) and a dicarboxylic acid component (for example, adipic acid) under the presence of water in a pressurizing state to polymerize them in a melting state while removing added water and condensation water.

Further, the polyamide (X) can be produced as well by a method in which the diamine component (for example, metaxylylenediamine) is added directly to the dicarboxylic acid component (for example, adipic acid) staying in a melting state to subject them to polycondensation under an atmospheric pressure. In the above case, the diamine component is continuously added to the dicarboxylic acid component in order to maintain the reaction system in an even liquid state, and during that time, the polycondensation is promoted wile heating the reaction system so that the reaction temperature is not lower than the melting points of oligoamide and polyamide each produced.

A small amount of monoamine and monocarboxylic acid may be added as a molecular weight controlling agent in the polycondensation of the polyamide (X).

Further, polycondensation may be carried out for the polyamide (X) by carrying out solid phase polymerization after produced by a melt polymerization method. The solid phase polymerization shall not specifically be restricted, and it can be carried out by an optional method on optional polymerization conditions.

The polycondensation for the polyamide (X) is carried out preferably under the presence of the phosphorus atom-containing compound (B) and the alkali metal compound (C). A sufficiently large amount of the phosphorus atom-containing compound (B) has to be added in order to prevent the polyamide (X) from being colored during the polycondensation, but if a use amount of the phosphorus atom-containing compound (B) is too large, not only the amidation reaction rate is accelerated too much to make it difficult to control the polymerization, but also production of gels and burnt deposits is likely to be brought about in the mold processing. Accordingly, the alkali metal compound (C) is preferably allowed to be coexistent from the viewpoint of controlling the amidation reaction rate.

The alkali metal compound (C) shall not specifically be restricted, and alkali metal hydroxides and alkali metal acetic acid salts can be listed as the preferred specific examples thereof. Lithium hydroxide, sodium hydroxide, potassium hydroxide, rubidium hydroxide and cesium hydroxide can be listed as the alkali metal hydroxides, and lithium acetate, sodium acetate, potassium acetate, rubidium acetate and cesium acetate can be listed as the alkali metal acetic acid salts.

When the alkali metal compound (C) is used in obtaining the polyamide (X) by polycondensation, a use amount of the alkali metal compound (C) falls in a range of preferably 0.5 to 1, more preferably 0.55 to 0.95 and further preferably 0.6 to 0.9 in terms of a value obtained by dividing a mole number of the alkali metal compound (C) by a mole number of the phosphorus atom-containing compound (B) from the viewpoint of inhibiting gels and burnt deposits from being produced.

<Step (b)>

The step (b) is a step in which the alkali compound (A) is added to the polyamide (x) obtained in the step (a) described above.

A molded article obtained by subjecting the polyamide (X) as it is to mold processing is excellent in properties and appearance immediately after starting molding, but generation of gels and burnt deposits is increased as the molding processing work is continued for a long time, and the quality of the product becomes unstable in a certain case. Particularly in a case of the film and the like, it is broken by the gels, and the apparatus can not help being stopped, so that the production efficiency is deteriorated. This is estimated to take place due to that the polyamide continues to stay locally between a melt-kneading part and a dice, whereby it is excessively heated and gelatinized and that the gels produced flow out. Further, in molding a bottle, the polyamide staying in an inside of a flow channel in a molding machine is deteriorated by excessively heating to result in generating burnt deposits, and they clog the flow channel and are mixed in the bottle of the product to deteriorate the quality of the bottle. In order to meet the above matters, the alkali compound (A) is added to the resulting polyamide (X) in the present invention in order to prevent gels and burnt deposits generated in the mold processing from being produced.

The present inventors have found from measurement of the molecular weight by a gel permeation chromatography that continuous heating of the polyamide in a molten state promotes polarization of the polyamide into a low molecular weight and a high molecular weight and that the more the high molecular weight component is present, the more the production amount of gels and burnt deposits is increased in the mold processing of the polyamide. A mechanism of generating burnt deposits is not apparent, and it is estimated that the polyamide stays and is excessively heated in an inside of the apparatus, that is, flow channel parts of the molten resin such as a screw, an inside of the extruding equipment, an inside of the die, a hot runner and the like, whereby a molecular weight thereof is elevated, so that flowing of the polyamide in the above parts is deteriorated; accordingly, the polyamide is liable to stay more and more in the above parts, and finally, the polyamide staying there is excessively heated to result in generating burnt deposits.

In contrast with this, the present inventors have found as well that the high molecular weight component is decreased by adding the alkali compound (A) to the polyamide. The reasons thereof have not yet been clarified and are estimated to be attributable to that particularly progress of amidation brought about during molding the polyamide resin composition is retarded by adding the alkali compound (A) to result in inhibiting an increase in the molecular weight; flow in an inside of the apparatus is maintained in a good state, and the polyamide can be prevented from being excessively heated; and as a result thereof, gels and burnt deposits are inhibited from being produced.

As described above, the same compounds as the examples of the alkali metal compound (C) which can be added in producing the polyamide (X) are also shown as the examples of the alkali compound (A). However, if the alkali metal compound (C) is excessively added in the melt polymerization, an effect of accelerating the amidation reaction of the phosphorus atom-containing compound (B) is inhibited too much to retard progress of the polycondensation, and the thermal history in producing the polyamide grows large to increase gels and burnt deposits in the mold processing of the polyamide in a certain case. Accordingly, increasing an amount of the alkali metal compound (C) added in producing the polyamide (X) by melt-polymerizing the monomer can not play a role of preventing gels and burnt deposits from being produced in the mold processing. In contrast with this, gels and burnt deposits can effectively be prevented from being produced in the mold processing in the present invention by adding the alkali compound (A) to the polyamide (X) obtained.

A use amount of the Alkali compound (A) is an amount in which a total mole concentration M of an alkali metal atom and an alkaline earth metal atom each contained per g of the polyamide resin composition falls in the range described above, and it is an amount in which M/P falls in the range described above.

A method for adding the alkali compound (A) to the polyamide (X) shall not specifically be restricted, and it can be added by an optional method. A method in which the polyamide (X) and the alkali compound (A) are molten and kneaded by means of an extrusion equipment is preferred.

Optional extrusion equipments such as a batch system kneading equipment, a kneader, a cokneader, a planetary extrusion equipment, a single shaft or double shaft extrusion equipment and the like can be used as the extrusion equipment. Among them, the single shaft extrusion equipment and the double shaft extrusion equipment are preferably used from the viewpoints of a kneading ability and a productivity.

Means for supplying the polyamide (X) and the alkali compound (A) to the extrusion equipment shall not specifically be restricted, and a belt feeder, a screw feeder, a vibration feeder and the like can be used. The polyamide (X) and the alkali compound (A) may be supplied respectively by independent feeders or may be dry-blended and then supplied.

A shape of the alkali compound (A) shall not specifically be restricted as long as it can evenly be dispersed in the resin composition, and it may be added as it is or may be added after molten by heating or may be added after dissolved in a solvent. When added as it is in the form of powder, a particle diameter thereof is preferably 0.01 to 5.0 mm, more preferably 0.02 to 3.0 mm. When the alkali compound (A) is added after dissolved in a solvent, it can be added to the extrusion equipment by means of an equipment such as a feeder for adding a solution and the like or can be blended as well in advance by means of a tumbler. Water and optional organic solvents can be used as the solvent.

The polyamide (X) and the alkali compound (A) may be mixed directly in the mold processing. Further, the polyamide (X) may be molten and kneaded with the alkali compound (A) having a high concentration by means of an extrusion equipment to prepare pellets, and then the above pellets may be blended with the polyamide (X) and subjected to mold processing. Alternatively, the above pellets may be blended with the polyamide (X) and subjected to solid phase polymerization, and then it may be subjected to mold processing.

Further, in order to prevent separation of the polyamide (X) from the alkali compound (A) after dry-blended, a viscous liquid may be adhered as a spreading agent to the polyamide (X), and then the alkali compound (A) may be added and mixed therewith. The spreading agent shall not specifically be restricted, and surfactants and the like can be used.

In the preferred production process for the polyamide resin composition of the present invention, the step (b) described above contains steps (b1) and (b2) shown below.

Step (b1): a step in which 90 to 99 parts by mass of the polyamide (X) and 10 to 1 parts by mass of the alkali compound (A) are molten and kneaded by means of an extrusion equipment to obtain a polyamide master batch (Y).

Step (b2): a step in which 0.5 to 20 parts by mass of the polyamide master batch (Y) obtained in the step (b1) described above and 99.5 to 80 parts by mass of the polyamide (X) are molten and kneaded.

In the above process, the polyamide (X) and the alkali compound (A) are molten and kneaded by means of the extrusion equipment to obtain the polyamide master batch (Y) containing the alkali compound (A) having a high concentration, and then the polyamide master batch (Y) obtained and the polyamide (X) are blended and then molten and kneaded to obtain a polyamide resin composition. Production of gels can be inhibited in a mold processing in which adding directly the alkali compound (A) to the polyamide (X). Further, using the polyamide master batch (Y) obtained by melting and kneading the polyamide (X) and the alkali compound (A), the alkali compound (A) can be enough dispersed in molding products, thereby obtaining the molding products having a more stable moldability and a good appearance without whitening and irregularities.

In the present invention, examples of the alkali compound (A) include hydroxides, hydrides, alkoxides, carbonates, hydrogencarbonates and carboxylates of alkali metals and alkaline earth metals, and anhydrous salts and hydrate salts thereof can be used. Mass ratio between the polyamide (X) and the alkali compound (A) in the polyamide master batch (Y) is calculated by reducing mass of the alkali compound (A) to an anhydrous salt equivalent mass even if the alkali compound (A) is a hydrate salt.

In the step (b1), a blend ratio (the polyamide (X)/the alkali compound (A)) of the polyamide (X) to the alkali compound (A) is preferably 90 to 99 parts by mass/10 to 1 parts by mass, more preferably 92 to 99 parts by mass/8 to 1 parts by mass and further preferably 94 to 98 parts by mass/6 to 2 parts by mass from the viewpoints of inhibiting a reduction in the viscosity and inhibiting production of gels and burnt deposits and coloring.

In the step (b2), a blend ratio (the polyamide master batch (Y)/the polyamide (X)) of the polyamide master batch (Y) to the polyamide (X) preferably 0.5 to 20 parts by mass/99.5 to 80 parts by mass, more preferably 0.5 to 10 parts by mass/99.5 to 90 parts by mass and further preferably 1 to 5 parts by mass/99 to 95 parts by mass from the viewpoints of the moldability and inhibiting production of gels and burnt deposits.

It is preferably that the polyamide master batch (Y) obtained in the step (b1) satisfies that a sum of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide master batch (Y) by valencies thereof respectively is 12 μmol/g or more and 900 μmol/g or less, and the alkali compound (A) satisfies the following conditions (i) and (ii):

(i) it is a carbonate, a hydrogencarbonate or a carboxylate having 10 or less carbon atoms of an alkali metal or an alkaline earth metal and

(ii) a melting temperature Tm of the alkali compound (A) is not higher than a melt-kneading temperature K.

[Polyamide Master Batch (Y)]

The polyamide master batch (Y) of the present invention is a polyamide master batch used for the production process for the polyamide resin composition according to the above. The polyamide master batch (Y) of the present invention is obtained by a step in which 90 to 99 parts by mass of the polyamide (X) comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and 10 to 1 parts by mass of the alkali compound (A) are molten and kneaded, and it is characterized by that a sum of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide master batch by valencies thereof respectively satisfies 12 μmol/g or more and 900 μmol/g or less and that the alkali compound (A) satisfies the following conditions (i) and (ii):

(i) it is a carbonate, a hydrogencarbonate or a carboxylate having 10 or less carbon atoms of an alkali metal or an alkaline earth metal and

(ii) a melting temperature Tm of the alkali compound (A) is not higher than a melt-kneading temperature K.

The polyamide master batch of the present invention contains the polyamide (X) and the alkali compound (A). The polyamide (X) and the alkali compound (A) have been described above. In this regard, the alkali compound (A) contained in the polyamide master batch of the present invention is required to satisfy the conditions (i) and (ii) described above from the viewpoint of a dispersibility.

In particular, a lower melting temperature Tm of the alkali compound (A) contained in the polyamide master batch of the present invention than a melt-kneading temperature K of the polyamide (X) and the alkali compound (A) makes it easy to mix the alkali compound (A) into the polyamide in molding by means of a kneader and makes it possible to disperse the alkali compound (A) evenly in the polyamide and obtain a molded article which is free of whitening and irregularities and which is excellent in an appearance and physical properties. A melting temperature Tm of the alkali compound (A) shows a melting point of the alkali compound (A), and when the alkali compound (A) is a hydrate, the melting temperature shows a decomposition temperature at which crystal water is molten and changed to a liquid state.

The specific examples of the alkali compound (A) satisfying the conditions (i) and (ii) described above include sodium carbonate decahydrate, magnesium carbonate trihydrate, sodium acetate trihydrate, lithium acetate dihydrate, magnesium acetate tetrahydrate, calcium acetate monohydrate, potassium oxalate monohydrate, monosodium maleate trihydrate, sodium citrate dihydrate, potassium citrate monohydrate, potassium succinate hydrate, sodium tartrate dihydrate, potassium tartrate hydrate and the like, but they shall not be restricted to the above compounds. One kind of the compounds described above may be used or two or more kinds thereof may be used in combination for the alkali compound (A) used in the polyamide master batch of the present invention. Among the compounds described above, sodium carbonate decahydrate or sodium acetate trihydrate is more preferred from the viewpoints of an economical efficiency, easiness of handling at ambient temperature, a moldability and an gelation-inhibiting effect.

A sum (hereinafter referred to as “a total mole concentration of an alkali metal atom and an alkaline earth metal atom”) m of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide master batch of the present invention by valencies thereof respectively is 12 to 900 μmol/g, preferably 122 to 600 μmol/g and more preferably 184 to 450 μmol/g from the viewpoint of preventing deposits on a molded article obtained by using the polyamide master batch. Controlling the total mole concentration of an alkali metal atom and an alkaline earth metal atom to 12 μmol/g or more makes it possible to reduce a blend amount of the polyamide master batch to the polyamide and makes it possible to inhibit gels from being produced without damaging the mold processability such as a reduction in the melt viscosity and the like. If the total mole concentration of an alkali metal atom and an alkaline earth metal atom exceeds 900 μmol/g, a reduction in a melt viscosity of the polyamide master batch itself is possible to be brought about, and production of the polyamide master batch is likely to be difficult. In addition thereto, uneven dispersion of the polyamide master batch in the polyamide resin composition is brought about, and the alkali compound (A) is likely to stay in a state in which it is present locally in the polyamide resin composition to provide the possibility that the satisfactory gel-inhibiting effect is not obtained.

Further, the polyamide master batch of the present invention can be blended with one or a plurality of other resins such as nylon 6, nylon 66, nylon 66,6, polyesters, polyolefins, phenoxy resins and the like as long as the object is not damaged. Further, capable of being added are additives including inorganic fillers such as glass fibers, carbon fibers and the like; tabular inorganic fillers such as glass flakes, talc, kaolin, mica, montmorillonite, organic clays and the like; impact resistant modifying materials such as various elastomers and the like; crystal nucleus agents; lubricants such as fatty acid amide base lubricants, fatty acid amide base compounds and the like; antioxidants such as copper compounds, organic or inorganic halogen base compounds, hindered phenol base antioxidants, hindered amine base antioxidants, hydrazine base antioxidants, sulfur base compounds, phosphorus base compounds and the like; coloring inhibitors; UV absorbers such as benzotriazole base UV absorbers and the like; additives such as mold releasing agents, plasticizers, coloring agents, flame retardants and the like; compounds containing cobalt metal, benzoquinones, anthraquinones and naphthoquinones which are compounds providing an oxygen scavenging ability.

A melt-kneading temperature K (° C.) in producing the polyamide master batch by means of an extrusion equipment is set so that preferably T+5≦K≦T+60, more preferably T+5≦K≦T+50 and further preferably T+5≦K≦T+40 is satisfied. In this regard, T represents a melting point (° C.) of the polyamide (X).

If the melt-kneading temperature K is lower than T+5 (° C.), a non-molten substance of the polyamide (X) is liable to be generated in a certain case, and inferior dispersion of the alkali compound (A) is liable to be brought about. If the melt-kneading temperature K is higher than T+60 (° C.), the polyamide (X) and the alkali compound (A) are liable to be reduced in a molecular weight and a viscosity due to thermal decomposition. Further, the melt kneading time is preferably 0.5 to 15 minutes from the viewpoints of a dispersibility and inhibiting thermal decomposition.

Also, a melting temperature Tm of the alkali compound (A) is, as described above, preferably not higher than the melt-kneading temperature K from the viewpoint of preventing whitening and irregularities in the molded article.

In the polyamide resin composition of the present invention produced by the process described above, gels can be inhibited from being produced in melt polymerization of the polyamide, and gels and burnt deposits can be inhibited from being produced as well in mold processing of the resin composition obtained.

In the present invention, an effect of inhibiting gels of the polyamide resin composition from being produced is evaluated by comparing a gel fraction of the polyamide heated at a fixed temperature for a fixed time in a molten state at a high pressure under the estimation of a state to which the polyamide is exposed in molding. When the resin heated under pressure is dipped in hexafluoroisopropanol (HFIP) for 24 hours, the resin which is not gelatinized is completely dissolved therein, but the resin which is gelatinized remains in the form of an insoluble component of a swollen state. The gel fraction is calculated from the above insoluble component. The gel fraction referred to in the present invention means a value determined in terms of a percentage by dividing a mass of a residue obtained by filtrating the above insoluble component under vacuum by a membrane filter and then drying it by a denominator which is a mass of the resin weighed in advance before dipping in HFIP.

A gel fraction of the polyamide resin composition of the present invention is smaller than a gel fraction of a polyamide resin composition produced without adding the alkali compound (A) after polymerizing the polyamide. This shows that gels are inhibited from being produced in mold processing of the polyamide resin composition of the present invention. A gel fraction of the polyamide resin composition of the present invention observed when it is allowed to stay for a prescribed time at 270 to 290° C. which is a resin temperature of the polyamide resin in mold processing is preferably ½ or less, more preferably ⅓ or less and further preferably ⅕ or less of a gel fraction observed when the polyamide resin composition produced without adding the alkali compound (A) is allowed to stay on the same conditions. The staying time can be set to, for example, 24, 36 or 72 hours.

An index showing that the polyamide resin composition of the present invention has a good appearance and good physical properties can be evaluated by an average production amount of fish eyes counted by observing the film prepared from the polyamide resin composition under a fish eye inspection equipment. A cause of generating fish eyes in the polyamide resin composition is considered to be attributable to, for example, flowing of gels generated in the molding machine and precipitation of insoluble matters from the polyamide resin composition. In the present invention, a count number of foreign matters having a circle-corresponding diameter of 20 μm or more is preferably 900 pieces or less, more preferably 700 pieces or less and further preferably 600 pieces or less per m² of the polyamide film having a thickness of 50 μm. If it exceeds 900 pieces, irregularities are visually confirmed to be present on the film surface, and the appearance is damaged. In addition thereto, breaking is likely to be brought about in molding, and therefore it is not preferred.

The polyamide resin composition of the present invention can be blended with one or a plurality of other resins such as nylon 6, nylon 66, nylon 66,6, polyesters, polyolefins, phenoxy resins and the like as long as the object is not damaged. Further, capable of being added are additives including inorganic fillers such as glass fibers, carbon fibers and the like; tabular inorganic fillers such as glass flakes, talc, kaolin, mica, montmorillonite, organic clays and the like; impact resistant modifying materials such as various elastomers and the like; crystal nucleus agents; lubricants such as fatty acid amide base lubricants, fatty acid amide base compounds and the like; antioxidants such as copper compounds, organic or inorganic halogen base compounds, hindered phenol base antioxidants, hindered amine base antioxidants, hydrazine base antioxidants, sulfur base compounds, phosphorus base compounds and the like; coloring inhibitors; UV absorbers such as benzotriazole base UV absorbers and the like; additives such as mold releasing agents, plasticizers, coloring agents, flame retardants and the like; compounds containing cobalt metal, benzoquinones, anthraquinones and naphthoquinones which are compounds providing an oxygen scavenging ability.

The polyamide resin composition of the present invention is excellent in a gas-barrier property and a transparency and has a stable melt characteristic. The polyamide resin composition of the present invention can be processed into various shapes such as sheets, films, injection-molded bottles, blow bottles, injection-molded cups and the like by making use of the above polyamide resin composition for at least a part thereof to prepare molded articles. It can be used preferably for packaging materials, packaging vessels and fiber materials.

A production method of the molded articles shall not specifically be restricted, and they can be produced by optional methods. They can be produced by, for example, extrusion molding and injection molding. Also, the molded articles obtained by extrusion molding and injection molding may be further subjected to mold processing by single shaft stretching, double shaft stretching, stretching blow and the like.

To be specific, they can be processed into films and sheets by an extrusion method in which a T die is equipped, an inflation film method and the like, and the raw material films obtained are further subjected to stretching processing, whereby stretched films and heat shrinkable films can be obtained. Further, injection-molded cups can be prepared by an injection molding method, and blow bottles can be prepared by a blow molding method. A preform is produced by injection molding, and then a bottle can be prepared from it by blow molding.

Also, they can be processed as well into films and sheets having a multilayer structure with other resins, for example, polyethylene, polypropylene, nylon 6 and PET, metal foils, papers and the like by methods such as extrusion laminate, coextrusion and the like. The processed films and sheets can be used for wraps, pouches of various shapes, cap materials for vessels, packaging vessels such as bottles, cups, trays, tubes and the like. Further, they can be processed as well into preforms and bottles having a multilayer structure with PET and the like by a multilayer injection molding method and the like.

Packaging vessels obtained by making use of the polyamide resin composition of the present invention are excellent in a gas-barrier property and a transparency. The above packing vessels can be charged with various products including, for example, liquid beverages such as carbonated beverages, juices, water, milk, Japanese sake, whisky, distilled spirits, coffee, tea, jelly beverages, health beverages and the like, seasonings such as seasoning liquids, sauces, soy sauces, dressings, liquid stocks, mayonnaises, fermented soybean pastes, grated spices and the like, paste foods such as jams, creams, chocolate pastes and the like, liquid foods represented by liquid processed foods such as liquid soups, cooked foods, pickles, stews and the like, crude noodles and boiled noodles such as buckwheat noodles, noodles, Chinese noodles and the like, rice before cooking such as milled rice, humidity-conditioned rice, non-washing rice and the like, cooked rice, high moisture foods represented by processed rice products such as boiled rice mixed with fishes and vegetables, festive red rice, rice gruel and the like; low moisture foods represented by powder seasonings such as powder soups, instant bouillons and the like, dried vegetables, coffee beans, coffee powder, tea, cakes prepared from cereals as raw materials; solid and liquid chemicals such as agricultural chemicals, insecticides and the like, liquid and paste drugs and medicines, skin lotions, skin creams, skin emulsions, hair dressings, hair dyes, shampoos, soaps, detergents and the like.

The polyamide resin composition of the present invention can be used as materials for gasoline tanks and hoses of cars, bikes and the like as a gasoline-barrier material. The polyamide resin composition of the present invention can also be used as a fiber material for monofilaments and the like.

[Multilayer Molded Articles]

The multilayer molded article of the present invention comprises an outermost layer, an innermost layer and at least one gas-barrier layer between the outermost layer and the innermost layer, and the polyamide resin composition of the present invention is used as the gas-barrier layer in order to prevent gels and burnt deposits from being produced in the mold processing. The multilayer molded article of the present invention is preferably a multilayer bottle obtained by blow-molding a multilayer preform by a hot parison method or a cold parison method.

(Polyester resin)

The outermost layer and the innermost layer in the multilayer molded article of the present invention are constituted from a polyester resin comprising a dicarboxylic acid unit containing 80 mol % or more of a terephthalic acid unit and a diol unit containing 80 mol % or more of an ethylene glycol unit. Also, the multilayer molded article of the present invention may have an intermediate layer if necessary, and it is constituted preferably from the polyester resin described above. The polyester resin constituting the outermost layer, the innermost layer and the intermediate layer may be the same of different.

The polyester resin constituting the outermost layer, the innermost layer and the intermediate layer in the multilayer molded article of the present invention is a polyester resin comprising a dicarboxylic acid unit containing 80 mol % or more, preferably 90 mol % or more of a terephthalic acid unit and a diol unit containing 80 mol % or more, preferably 90 mol % or more of an ethylene glycol unit. The above polyester resin is obtained by subjecting a dicarboxylic acid component containing 80 mol % or more, preferably 90 mol % or more of terephthalic acid and a diol component containing 80 mol % or more, preferably 90 mol % or more of ethylene glycol to polycondensation reaction.

Polyethylene terephthalate is suitably used as the polyester resin. Excellent characteristics can be exerted in all of a transparency, a mechanical strength, an injection moldability and a stretching blow moldability with which polyethylene terephthalate is provided.

Isophthalic acid, diphenyl ether-4,4-dicarboxylic acid, naphthalene-1,4, or 2,6-dicarboxylic acid, adipic acid, sebacic acid, decane-1,10-carboxylic acid and hexahydroterephthalic acid can be as the dicarboxylic acid component other than terephthalic acid. Also, propylene glycol, 1,4-butanediol, neopentyl glycol, diethylene glycol, cyclohexanedimethanol, 2,2-bis(4-hydroxyphenyl)propane, 2,2-bis(4-hydroxyethoxyphenyl)propane and the like can be as the diol component other than ethylene glycol. Further, oxyacids such as p-oxybenzoic acid and the like can also be used as a raw material monomer for the polyester resin.

An intrinsic viscosity of the polyester resin is preferably 0.55 to 1.30, more preferably 0.65 to 1.20. If the intrinsic viscosity is 0.55 or more, the multilayer preform can be obtained in a transparent amorphous state, and the multilayer bottle obtained has a satisfactory mechanical strength. Further, if the intrinsic viscosity is 1.30 or less, the bottle is readily molded without damaging a fluidity in molding.

The outermost layer and the innermost layer in the multilayer molded article of the present invention may contain other thermoplastic resins and various additives in the polyester resin as long as the characteristics of the present invention are not damaged, but the polyester resin accounts preferably for 90% by mass or more.

Thermoplastic polyester resins such as polyethylene 2,6-naphthalenedicaboxylate and the like, polyolefin base resins, polycarbonate, polyacrylonitrile, polyvinyl chloride, polystyrene and the like can be shown as the examples of the thermoplastic resins described above.

Further, UV absorbers, oxygen absorbers, coloring agents, IR absorbers (reheat additives) for accelerating heating of a preform to shorten recycling time in molding and the like can be shown as the examples of the additives described above.

(Production Method of Multilayer Molded Article)

The multilayer molded article of the present invention, particularly the multilayer bottle is obtained by injecting the polyester resin from an injection cylinder at a skin side and the polyamide resin from an injection cylinder at a core side into a metal die cavity through a metal die hot runner by means of an injection molding machine equipped with two injection cylinders to obtain a multilayer preform and subjecting the preform obtained above to double shaft stretching blow molding by a publicly known method. Alternatively, it is obtained by extruding the polyester resin from an extruding equipment at a skin side and the polyamide resin from an extruding equipment at a core side in a cylindrical form by means of a blow molding machine equipped with two extruding equipments and subjecting the extruded matter intermittently to blow molding. Also, an adhesive resin layer may be provided, if necessary, between the layers.

In general, publicly known methods such as a so-called cold parison method, a so-called hot parison method and the like are available as a method for blow-molding a multilayer preform which is a precursor. It includes, for example, a method in which the multilayer preform is heated on a surface at 80 to 120° C. and then stretched in an axial direction by a mechanical means such as pushing by a core rod insert and in which it is then stretched in a lateral direction and blow-molded by blowing high pressure air of usually 2 to 4 MPa and a method in which the multilayer preform is crystallized in a mouth part and heated on a surface at 80 to 120° C. and in which it is then blow-molded in a metal die of 90 to 150° C.

In the present invention, a heating temperature of the preform is preferably 90 to 110° C., more preferably 95 to 108° C. If a heating temperature of the preform is lower than 90° C., heating is insufficient, and the gas-barrier layer or the PET layer is cold-stretched and whitened in a certain case. If it is higher than 110° C., the gas-barrier layer is crystallized and whitened in a certain case. Further, the interlayer peeling resistant performance is reduced as well in a certain case.

In the present invention, because of an excellent gas-barrier property and an excellent moldability, the multilayer bottle has preferably a three layer structure of a polyester resin layer/a gas-barrier layer/a polyester resin layer or a five layer structure of a polyester resin layer/a gas-barrier layer/a polyester resin layer/a gas-barrier layer/a polyester resin layer.

The multilayer bottle of a three layer structure or a five layer structure is obtained by subjecting a multilayer preform of a three layer structure or a five layer structure to double shaft stretching blow molding by a publicly known method. A production method for the multilayer preform of a three layer structure or a five layer structure shall not specifically be restricted, and publicly known methods can be used. For example, in a step in which the polyester resin constituting the innermost layer and the outermost layer is injected from a skin side injection cylinder and in which the resin constituting the gas-barrier layer is injected from a core side injection cylinder, the polyester resin is first injected, and then the resin constituting the gas-barrier layer and the polyester resin are injected at the same time; next, a required amount of the polyester resin is injected to fulfill a metal die cavity, whereby the multilayer preform of a three layer structure (a polyester resin layer/a gas-barrier layer/a polyester resin layer) can be produced.

Further, in a step in which the polyester resin constituting the innermost layer and the outermost layer is injected from a skin side injection cylinder and in which the resin constituting the gas-barrier layer is injected from a core side injection cylinder, the polyester resin is first injected, and then the resin constituting the gas-barrier layer is injected separately; finally, the polyester resin is injected to fulfill a metal die cavity, whereby the multilayer preform of a five layer structure (a polyester resin layer/a gas-barrier layer/a polyester resin layer/a gas-barrier layer/a polyester resin layer) can be produced.

The method for producing the multilayer preform shall not be restricted to the methods described above.

A thickness of the polyester resin layer in the multilayer preform is preferably 0.01 to 1.0 mm, and a thickness of the gas-barrier layer is preferably 0.005 to 0.2 mm (5 to 200 μm). A thickness of the multilayer bottle does not have to be fixed over a whole part of the bottle and falls usually in a range of 0.2 to 1.0 mm.

In the multilayer bottle obtained by subjecting the multilayer preform to double shaft stretching blow molding, the gas-barrier performance can be exerted as long as the gas-barrier layer is present at least on a barrel part of the multilayer bottle, and if the gas-barrier layer is extended up to a tip vicinity of a stopper part in the multilayer bottle, the gas-barrier performance is further better.

In the multilayer molded article of the present invention, a mass of the gas-barrier layer accounts for preferably 1 to 20% by mass, more preferably 2 to 15% by mass and particularly preferably 3 to 10% by mass based on a total mass of the multilayer bottle. Controlling a mass of the gas-barrier layer to the ranges described above provides the multilayer bottle having a good gas-barrier property and makes it easy to mold the multilayer preform which is a precursor into the multilayer bottle.

The multilayer molded article of the present invention provides less burnt deposit mixed in the products. The multilayer molded article of the present invention is suitable for receiving and storing various products including, for example, liquid beverages such as carbonated beverages, juices, water, milk, Japanese sake, whisky, distilled spirits, coffee, tea, jelly beverages, health beverages and the like, seasonings such as seasoning liquids, sauces, soy sauces, dressings, liquid stocks and the like, liquid foods such as liquid soups and the like, liquid drugs and medicines, skin lotions, skin emulsions, hair dressings, hair dyes, shampoos and the like. The multilayer molded article of the present invention generates less burnt deposit in production and prevents the burnt deposits from clogging flow channels in an inside of a molding machine, and it can cut a labor hour for maintenance of the apparatus and contribute to stable production of the multilayer bottle and the like.

EXAMPLES

The present invention shall be explained below in further details with reference to examples, but the present invention shall not be restricted to them.

[Measurement of Physical Properties of Polyamide Resin Composition and Polyamide Master Batch]

A relative viscosity of the polyamide resin composition, a total mole concentration M of an alkali metal atom and an alkaline earth metal atom and a mole concentration P of a phosphorus atom in the polyamide resin composition and a total mole concentration m of an alkali metal atom and an alkaline earth metal atom in the polyamide master batch were measured by the following methods.

(1) Relative Viscosity of the Polyamide Resin Composition:

1 gram of the polyamide resin composition was precisely weighed and dissolved in 100 ml of 96 mass % sulfuric acid at 20 to 30° C. by stirring. After completely dissolved, 5 ml of the solution was immediately put in a Cannon-Fenske viscometer and left standing in a thermostatic bath of 25° C. for 10 minutes, and then a falling time (t) thereof was measured. Further, a falling time (t₀) of 96 mass % sulfuric acid itself was measured as well in the same manner. The relative viscosity was calculated from t and t₀ according to the following equation:

Relative viscosity=t/t₀

(2) Total Mole Concentration M of an Alkali Metal Atom Concentration and an Alkaline Earth Metal Atom Concentration and a Mole Concentration P of a Phosphorus Atom:

A total mole concentration M of an alkali metal atom and an alkaline earth metal atom and a mole concentration P of a phosphorus atom each contained per g of the polyamide resin composition were quantitatively determined by means of an atomic absorption spectrometer (trade name: AA-6650, manufactured by Shimadzu Corporation) and an ICP emission spectrometer (trade name: ICPE-9000, manufactured by Shimadzu Corporation) after the polyamide resin composition was subjected to decomposition treatment in nitric acid by a microwave. The measured values were obtained in terms of a mass ratio (ppm), and therefore M and P were calculated by using the atomic masses and the valencies.

(3) Total mole concentration m of an alkali metal atom and an alkaline earth metal atom contained per g of the polyamide master batch:

A total mole concentration m of an alkali metal atom and an alkaline earth metal atom each contained per g of the polyamide master batch was quantitatively determined by means of the atomic absorption spectrometer (trade name: AA-6650, manufactured by Shimadzu Corporation) and the ICP emission spectrometer (trade name: ICPE-9000, manufactured by Shimadzu Corporation) after the polyamide master batch was subjected to decomposition treatment in nitric acid by a microwave. The measured value was obtained in terms of a mass ratio (ppm), and therefore m was calculated by using the atomic masses and the valencies.

[Evaluation of Film]

The films obtained in the example and the comparative example were evaluated by the following methods.

(1) Fish Eye Number:

The films obtained in the example and the comparative example were allowed to pass between a camera of a fish eye inspection equipment and a light source and reeled on a reeling equipment, and a fish eye number (circle-corresponding diameter: 20 μm or more) of the film having a width of 10 cm, a length of 50 m and a thickness of 50 μm was counted when one hour passed since starting extrusion to calculate the fish eye number per m². The smaller the fish eye number is, the more preferable.

(2) Resin Pressure of Extrusion Equipment Head:

After finishing counting of the fish eye number, the reeling velocity was adjusted to prepare a film having a width of 15 cm and a thickness of 250 μm. Then, the extrusion was continued to measure the resin pressures of the extrusion equipment head immediately after starting the extrusion, after 3 hours passed and after 6 hours passed respectively, and the presence of a change thereof was measured. A smaller change amount of the resin pressures of the extrusion equipment head is preferred.

(3) Appearance of the Film:

The appearance of the films obtained was visually observed. It is preferred that coloring and foreign matters such as gels and the like are not observed in the films.

(4) Gel Fraction:

(Preparation of Staying Sample)

The film having a thickness of 250 μm described above was cut in a form of a circle having a diameter of 30 mm, and four sheets thereof were prepared. The above circular films were concentrically superposed and inserted into a hole part of a 100×100 mm polytetrafluoroethylene sheet of 1 mm thickness having a hole bored in a diameter of 30 mm, and further, the above sheet was interposed between two 100×100 mm polytetrafluoroethylene sheets of 1 mm thickness.

Next, the foregoing polytetrafluoroethylene sheets which interposed the film described above therebetween were disposed in a center of the groove in a 150×150 mm metal plate of 15 mm thickness having a 120×120 mm groove of 3 mm depth in a central part, and further, it was covered thereon with a 150×150 mm metal plate of 15 mm thickness. Then, the metal plates were fixed by a bolt.

Subsequently, the metal plates were heated on the respective conditions of 72 hours at 270° C., 24 hours at 290° C. or 36 hours at 290° C. in a state in which the above metal plates were interposed at 50 kg/cm² or more by a hot press equipment heated in advance. After each time passed, the above metal plates were taken out and quenched, and after they were sufficiently cooled down to room temperature, the staying sample was taken out.

(Calculation of Gel Fraction)

Next, the staying sample described above was dried at 60° C. for 30 minutes in a constant temperature dryer, and then 100 mg of the dried sample was immediately weighed. The weighed staying sample was dipped in 10 ml of hexafluoroisopropanol (HFIP) having a purity of 99% for 24 hours, and then it was filtrated under vacuum through a polytetrafluoroethylene-made membrane filter having a pore diameter of 300 μm which was weighed in advance. A residue remaining on the membrane filter was washed three times by 2 ml of HFIP, and then the filter having the residue attached thereon was dried at 60° C. for 30 minutes in a constant temperature dryer.

A total mass of the residue and the filter which were dried was weighed, and an amount (gel amount) of an HFIP-insoluble component in the staying sample was calculated from a difference thereof from a mass of the membrane filter which was weighed in advance. The gel fraction was determined in terms of % by mass of the HFIP-insoluble component based on the staying sample before dipped in HFIP.

The same operation was carried out three times on the same conditions from preparation of the staying sample, and an average value of the gel fraction in the respective conditions was determined.

[Evaluation of Multilayer Molded Article (Preform)]

The preforms obtained in the example and the comparative example were evaluated by the following methods.

(1) Number of Burnt Deposits Generated:

A three layer preform (27 g) comprising a polyester resin layer/a gas-barrier layer/a polyester resin layer was injection-molded in 2,500 shots to obtain 10,000 sheets of the preforms. Among the preforms obtained, the number of the preforms having burnt deposits was counted.

(2) Stability of Preforms (PFM):

It was visually judged whether or not a barrier layer was stably present in the preform. Four sheets of the preforms obtained by injection in one cycle were cut in a vertical direction, and an iodine tincture was applied on a cross section thereof to dye only a polyamide resin composition layer (barrier layer), whereby it was confirmed whether or not the present positions of the barrier layers in the four preforms were aligned. If the barrier layers are not stably present, the present positions of the barrier layers in a neck part of the preforms are scattered, and the quality of the resulting products is deteriorated.

(3) Weighing Time:

Measured was time required for weighing a prescribed amount of the resin composition in a cylinder for melting and injection-molding the polyamide resin composition in molding the preform. The too long weighing time means that the moldability is inferior.

Example 101

(Melt Polymerization of Polyamide)

A reaction vessel having a content volume of 50 liter equipped with a stirrer, a partial condenser, a full condenser, a thermometer, a dropping funnel, a nitrogen introducing tube and a strand die was charged with 15,000 g (102.6 mole) of adipic acid precisely weighed, 432.6 mg (4.082 mmol, 5 ppm in terms of a phosphorus atom concentration in the polyamide) of sodium hypophosphite monohydrate (NaH₂PO₂.H₂O) and 206.4 mg (2.516 mmol, 0.62 in terms of a mole number ratio based on sodium hypophosphite monohydrate) of sodium acetate and sufficiently substituted with nitrogen, and then the vessel was heated up to 170° C. while stirring an inside of the system under a small amount of nitrogen flow. Metaxylylenediamine 13,895 g (102.0 mol) was dropwise added thereto while stirring, and an inside of the system was continuously heated while removing condensation water produced to an outside of the system. After finishing dropwise adding metaxylylenediamine, the internal temperature was controlled to 260° C. to continue the reaction for 40 minutes. Then, an inside of the system was pressurized by nitrogen to take out the polymer from the strand die, and this was pelletized to obtain about 24 kg of polyamide.

(Solid Phase Polymerization of Polyamide)

Next, a jacket-equipped tumble dryer in which a nitrogen gas introducing tube, a vacuum line, a vacuum pump and a thermocouple for measuring an inner temperature were provided was charged with the polyamide described above, and an inside of the tumble dryer was sufficiently substituted with nitrogen having a purity of 99% by volume or more while rotating it at a fixed speed. Then, the tumble dryer was heated under nitrogen gas flow, and the pellet temperature was elevated up to 150° C. in about 150 minutes. When the pellet temperature reached 150° C., a pressure in the system was reduced to 1 Torr or less. The temperature was further continued to be elevated, and after the pellet temperature was elevated up to 200° C. in about 70 minutes, the system was maintained at 200° C. for 30 to 45 minutes. Then, a nitrogen gas having a purity of 99% by volume or more was introduced into the system, and the tumble dryer was cooled while rotating to obtain polyamide (X101).

(Preparation of Polyamide Resin Composition (101))

Sodium acetate 400 mg (200 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X101) obtained and stirred and mixed to thereby prepare a polyamide resin composition (101).

(Production of Film)

Next, a film was produced by means of a film extrusion equipment comprising a 25 mmφ single shaft extrusion equipment, a head provided with a filter of 600 mesh and a T die and a receiving equipment equipped with a cooling roll, a fish eye inspection equipment (model: GX70W, manufactured by Mamiya-OP Co., Ltd.) and a reeling device. The polyamide resin composition (101) was extruded in a film form from the extrusion equipment while maintaining a discharge rate of 3 kg/hour, and the receiving velocity was adjusted to prepare a film having a width of 15 cm and a thickness of 50 μm.

Example 102

A polyamide resin composition (102) was prepared in the same manner as in Example 101, except that an addition amount of sodium acetate to the polyamide (X101) in Example 101 was changed to 600 mg (300 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (102) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 103

A polyamide resin composition (103) was prepared in the same manner as in Example 101, except that an addition amount of sodium acetate to the polyamide (X101) in Example 101 was changed to 800 mg (400 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (103) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 104

A polyamide resin composition (104) was prepared in the same manner as in Example 101, except that an addition amount of sodium acetate to the polyamide (X101) in Example 101 was changed to 1,200 mg (600 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (104) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 105

A polyamide resin composition (105) was prepared in the same manner as in Example 101, except that an addition amount of sodium acetate to the polyamide (X101) in Example 101 was changed to 4,000 mg (2,000 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (105) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 106

Sodium n-propionate 3,000 mg (1,500 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X101) obtained in Example 101 and mixed by stirring to thereby prepare a polyamide resin composition (106), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (106) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 107

Sodium n-hexanoate 4,000 mg (2,000 ppm to the polyamide) was added to 2 kg of the polyamide (X101) obtained in Example 101 and mixed by stirring to thereby prepare a polyamide resin composition (107), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (107) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 108

Sodium caprate 4,000 mg (2,000 ppm to the polyamide) was added to 2 kg of the polyamide (X101) obtained in Example 101 and mixed by stirring to thereby prepare a polyamide resin composition (108), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (108) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 109

Disodium adipate 2,000 mg (1,000 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X101) obtained in Example 101 and mixed by stirring to thereby prepare a polyamide resin composition (109), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (109) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 110

Sodium carbonate decahydrate 2,000 mg (1,000 ppm to the polyamide) was added to 2 kg of the polyamide (X101) obtained in Example 101 to thereby prepare a polyamide resin composition (110), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (110) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 111

Melt polymerization and pelletization were carried out in the same manners as in Example 101 to obtain about 24 kg of polyamide, except that in preparation of the polyamide in Example 101, an addition amount of sodium hypophosphite monohydrate was changed to 86.5 mg (0.816 mmol, 1 ppm in terms of a phosphorus atom concentration in the polyamide) and that an addition amount of sodium acetate was changed to 41.3 mg (0.503 mmol, 0.62 in terms of a mole number ratio based on sodium hypophosphite monohydrate). Then, solid phase polymerization was carried out in the same manner as in Example 101 to obtain polyamide (X102).

Sodium acetate 400 mg (200 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X102) obtained above and mixed by stirring to thereby prepare a polyamide resin composition (111), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (111) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 112

Melt polymerization and pelletization were carried out in the same manners as in Example 101 to obtain about 24 kg of polyamide, except that in preparation of the polyamide in Example 101, an addition amount of sodium hypophosphite monohydrate was changed to 173.1 mg (1.633 mmol, 2 ppm in terms of a phosphorus atom concentration in the polyamide) and that an addition amount of sodium acetate was changed to 82.6 mg (1.007 mmol, 0.62 in terms of a mole number ratio based on sodium hypophosphite monohydrate). Then, solid phase polymerization was carried out in the same manner as in Example 101 to obtain polyamide (X103).

Sodium acetate 400 mg (200 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X103) obtained above and mixed by stirring to thereby prepare a polyamide resin composition (112), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (112) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 113

Melt polymerization and pelletization were carried out in the same manners as in Example 101 to obtain about 24 kg of polyamide, except that in preparation of the polyamide in Example 101, an addition amount of sodium hypophosphite monohydrate was changed to 778.7 mg (7.343 mmol, 9.5 ppm in terms of a phosphorus atom concentration in the polyamide) and that an addition amount of sodium acetate was changed to 371.6 mg (4.53 mmol, 0.62 in terms of a mole number ratio based on sodium hypophosphite monohydrate). Then, solid phase polymerization was carried out in the same manner as in Example 101 to obtain polyamide (X104).

Sodium acetate 400 mg (200 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X104) obtained above and mixed by stirring to thereby prepare a polyamide resin composition (113), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (113) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 114

A polyamide resin composition (114) was prepared in the same manner as in Example 113, except that an addition amount of sodium acetate to the polyamide (X104) in Example 113 was changed to 4,000 mg (2,000 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (114) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 115

Lithium acetate dihydrate 2,000 mg (1,000 ppm to the polyamide) was added to 2 kg of the polyamide (X101) obtained in Example 101 and mixed by stirring to thereby prepare a polyamide resin composition (115), and the physical properties thereof were measured in the same manner as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (115) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Example 116

Potassium acetate 2,000 mg (1,000 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X101) obtained in Example 101 and mixed by stiffing to thereby prepare a polyamide resin composition (116), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (116) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 101

The physical properties of the polyamide (X101) obtained in Example 101 were measured in the same manners as in Example 101. Further, a film was produced in the same manner as in Example 101, except that the polyamide (X101) was used and that sodium acetate was not added, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 102

A polyamide resin composition (117) was prepared in the same manner as in Example 101, except that an addition amount of sodium acetate to the polyamide (X101) in Example 101 was changed to 200 mg (100 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (117) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 103

A polyamide resin composition (118) was prepared in the same manner as in Example 101, except that an addition amount of sodium acetate to the polyamide (X101) in Example 101 was changed to 6,000 mg (3,000 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (118) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 104

A polyamide resin composition (119) was prepared in the same manner as in Example 106, except that an addition amount of sodium n-propionate to the polyamide (X101) in Example 106 was changed to 100 mg (50 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (119) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 105

A polyamide resin composition (120) was prepared in the same manner as in Example 107, except that an addition amount of sodium n-hexanoate to the polyamide (X101) in Example 107 was changed to 100 mg (50 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (120) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 106

A polyamide resin composition (121) was prepared in the same manner as in Example 108, except that an addition amount of sodium caprate to the polyamide (X101) in Example 108 was changed to 150 mg (75 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (121) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 107

Melt polymerization and pelletization were carried out in the same manners as in Example 101 to obtain about 24 kg of polyamide, except that in preparation of the polyamide in Example 101, an addition amount of sodium hypophosphite monohydrate was changed to 43.3 mg (0.408 mmol, 0.5 ppm in terms of a phosphorus atom concentration in the polyamide) and that an addition amount of sodium acetate was changed to 20.6 mg (0.252 mmol, 0.62 in terms of a mole number ratio based on sodium hypophosphite monohydrate). Then, solid phase polymerization was carried out in the same manner as in Example 101 to obtain polyamide (X105).

Sodium acetate 400 mg (200 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X105) obtained above and mixed by stirring to thereby prepare a polyamide resin composition (122), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (122) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 108

A polyamide resin composition (123) was prepared in the same manner as in Comparative Example 107, except that an addition amount of sodium acetate to the polyamide (X105) in Comparative Example 107 was changed to 2,000 mg (1,000 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (123) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 109

A polyamide resin composition (124) was prepared in the same manner as in Example 113, except that an addition amount of sodium acetate to the polyamide (X104) in Example 113 was changed to 6,000 mg (3,000 ppm to the polyamide), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (124) was used, and it was evaluated. The results thereof are shown in Tables 1 and 2.

Comparative Example 110

Melt polymerization and pelletization were carried out in the same manners as in Example 101 to obtain about 24 kg of polyamide, except that in preparation of the polyamide in Example 101, an addition amount of sodium hypophosphite monohydrate was changed to 1,297.8 mg (12.24 mmol, 14.5 ppm in terms of a phosphorus atom concentration in the polyamide) and that an addition amount of sodium acetate was changed to 619.3 mg (7.549 mmol, 0.62 in terms of a mole number ratio based on sodium hypophosphite monohydrate). Then, solid phase polymerization was carried out in the same manner as in Example 101 to obtain polyamide (X106).

Sodium acetate 2,000 mg (1,000 ppm to the polyamide) dissolved in 5 ml of distilled warm water was added to 2 kg of the polyamide (X106) obtained above and mixed by stirring to thereby prepare a polyamide resin composition (125), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (125) was used. The filter in the resin line was clogged in producing the film, and the resin pressure was elevated with the passage of time. The film obtained was evaluated in the same manners as in Example 101. The results thereof are shown in Tables 1 and 2.

Example 117

Sodium acetate 400 g dissolved in 350 ml of warm water was added to 9.60 kg of the polyamide (X101) obtained in Example 101 and mixed by stirring, and the mixture thus obtained was turned into a strand form by means of a double shaft extrusion equipment (model: TEM37BS, bore diameter: 37 mmφ, manufactured by Toshiba Machine Co., Ltd.) equipped with a strand die. Next, it was cooled in a water-cooled bath and then pelletized by means of a pelletizer. Thereafter, the pellets were dried at 0.1 Torr or less and 140° C. for 8 hours by means of a vacuum dryer to obtain polyamide master batch (Y101).

The polyamide (X101) 1,975.0 g and the polyamide master batch (Y101) 25.0 g were mixed to thereby prepare a polyamide resin composition (126), and the physical properties thereof were measured in the same manners as in Example 101. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (126) was used, and it was evaluated. The results thereof are shown in Tables 3 and 4.

Example 118

A polyamide resin composition (127) was prepared in the same manners as in Example 117, except that the blend amounts of the polyamide (X101) and the polyamide master batch (Y101) in Example 117 were changed to 1,950.0 g of the polyamide (X101) and 50.0 g of the polyamide master batch (Y101) respectively, and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (127) was used, and it was evaluated. The results thereof are shown in Tables 3 and 4.

Example 119

A polyamide resin composition (128) was prepared in the same manners as in Example 117, except that the blend amounts of the polyamide (X101) and the polyamide master batch (Y101) in Example 117 were changed to 1,925.0 g of the polyamide (X101) and 75.0 g of the polyamide master batch (Y101) respectively, and the physical properties thereof were measured. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (128) was used, and it was evaluated.

The results thereof are shown in Tables 3 and 4.

Example 120

A double shaft extrusion equipment equipped with a strand die was used to supply the polyamide (X101) obtained in Example 101 at a discharge velocity of 28.8 kg/hour and sodium acetate trihydrate at a discharge velocity of 1.2 kg/hour respectively by different feeders to turn the polyamide into a strand form. Next, it was cooled in a water-cooled bath and then pelletized by means of a pelletizer. Thereafter, the pellets were dried at 0.1 Ton or less and 140° C. for 8 hours by means of a vacuum dryer to obtain polyamide master batch (Y102).

A polyamide resin composition (129) was prepared in the same manners as in Example 117, except that the polyamide master batch (Y101) in Example 117 was changed to the polyamide master batch (Y102), and the physical properties thereof were measured. Further, a film was produced in the same manner as in Example 101, except that the polyamide resin composition (129) was used, and it was evaluated. The results thereof are shown in Tables 3 and 4.

Example 121

A polyamide resin composition (130) was prepared in the same manners as in Comparative Example 120, except that the blend amounts of the polyamide (X101) and the polyamide master batch (Y102) in Example 120 were changed to 1,950.0 g of the polyamide (X101) and 50.0 g of the polyamide master batch (Y102) respectively, and the physical properties thereof were measured. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (130) was used, and it was evaluated. The results thereof are shown in Tables 3 and 4.

Example 122

A polyamide resin composition (131) was prepared in the same manners as in Example 120, except that the blend amounts of the polyamide (X101) and the polyamide master batch (Y102) in Example 120 were changed to 1,925.0 g of the polyamide (X101) and 75.0 g of the polyamide master batch (Y102) respectively, and the physical properties thereof were measured. Further, a film was produced in the same manners as in Example 101, except that the polyamide resin composition (131) was used, and it was evaluated. The results thereof are shown in Tables 3 and 4.

Abbreviated expressions in the tables show the followings respectively.

• AcNa: Sodium acetate
• AcNa.3H₂O: Sodium acetate trihydrate
• PrNa: Sodium n-propionate
• HxNa: Sodium n-hexanoate
• DecNa:Sodium caprate (sodium n-decanoate)
• AdNa: Disodium adipate
• Na₂CO₃.10H₂O: Sodium carbonate decahydrate
• AcLi.2H₂O: Lithium acetate dihydrate
• AcK: Potassium acetate

	TABLE 1
	Alkali compound (A) (*)	P	M
	Kind	[ppm]	[μmol/g]	[μmol/g]	M/P
Example 101	AcNa	200	0.16	2.69	16.8
Example 102	AcNa	300	0.16	3.99	24.9
Example 103	AcNa	400	0.16	5.19	32.4
Example 104	AcNa	600	0.16	7.44	46.5
Example 105	AcNa	2000	0.16	24.41	152.6
Example 106	PrNa	1500	0.16	15.20	95.0
Example 107	HxNa	2000	0.16	14.10	88.1
Example 108	DecNa	2000	0.16	10.45	65.3
Example 109	AdNa	1000	0.16	10.23	63.9
Example 110	Na2CO3•10H2O	1000	0.16	7.11	44.4
Example 111	AcNa	200	0.03	2.44	81.3
Example 112	AcNa	200	0.06	2.49	41.5
Example 113	AcNa	200	0.31	2.89	9.3
Example 114	AcNa	2000	0.31	24.20	78.1
Example 115	AcLi•2H2O	1000	0.16	9.90	61.9
Example 116	AcK	1000	0.16	9.90	61.9
Comparative	No addition	—	0.16	0.28	1.8
Example 101
Comparative	AcNa	100	0.16	0.57	3.6
Example 102
Comparative	AcNa	3000	0.16	36.96	231.0
Example 103
Comparative	PrNa	50	0.16	0.77	4.8
Example 104
Comparative	HxNa	50	0.16	0.81	5.1
Example 105
Comparative	DecNa	75	0.16	0.66	4.1
Example 106
Comparative	AcNa	200	0.02	2.30	115.0
Example 107
Comparative	AcNa	1000	0.03	12.56	418.7
Example 108
Comparative	AcNa	3000	0.31	36.90	119.0
Example 109
Comparative	AcNa	1000	0.47	12.29	26.1
Example 110
(*) Concentration of the alkali compound (A) to the polyamide
P: Mole concentration of a phosphorus atom contained per 1 gram of the polyamide resin composition
M: Total mole concentration of an alkali metal atom and an alkaline earth metal atom each contained per 1 gram of the polyamide resin composition

	TABLE 2
	Resin pressure average value	Fish eye		Relative	Gel fraction [%]
	[MPa]	number		viscosity	270° C.	290° C.	290° C.
	Immediately			of film	Appearance	of film	72 hr	24 hr	36 hr
	after starting	3 hr	6 hr	[/m2]	of film	(ηr′)	stay	stay	stay
Example 101	2.1	2.1	2.1	300	Good	2.58	13.3	14.3	18.9
Example 102	2.1	2.1	2.1	290	Good	2.57	9.9	8.9	15.5
Example 103	2.1	2.1	2.1	290	Good	2.57	6.4	5.4	9.9
Example 104	2.0	2.0	2.0	300	Good	2.55	4.3	4.1	7.2
Example 105	1.6	1.6	1.6	450	Good	2.52	0.6	0.8	3.3
Example 106	1.9	1.9	1.9	300	Good	2.55	4.9	5.9	8.8
Example 107	1.8	1.8	1.8	390	Good	2.53	4.6	1.1	5.4
Example 108	1.8	1.8	1.8	330	Good	2.53	1.8	2.5	9.1
Example 109	1.9	1.9	1.9	320	Good	2.55	1.2	2.4	8.9
Example 110	2.0	2.0	2.0	480	Good	2.60	2.2	1.2	6.6
Example 111	2.0	2.0	2.0	500	Good	2.56	14.1	14.4	20.1
Example 112	2.1	2.1	2.1	350	Good	2.56	14.1	14.8	20.0
Example 113	2.0	2.0	2.1	350	Good	2.56	13.2	13.1	17.9
Example 114	1.7	1.7	1.7	470	Good	2.51	1.9	0.3	3.6
Example 115	1.8	1.8	1.8	370	Good	2.55	2.9	3.1	5.5
Example 116	1.8	1.8	1.8	450	Good	2.55	3.0	2.0	5.6
Comparative	2.3	2.3	2.4	290	Good	2.65	35.6	30.6	51.2
Example 101
Comparative	2.1	2.1	2.1	310	Good	2.59	27.1	23.2	42.9
Example 102
Comparative	1.4	1.4	1.4	990	Irregularities	2.50	1.4	0.8	2.0
Example 103
Comparative	2.1	2.1	2.1	320	Good	2.60	34.2	35.7	46.9
Example 104
Comparative	2.1	2.1	2.1	340	Good	2.59	27.7	29.8	48.9
Example 105
Comparative	2.0	2.0	1.9	300	Good	2.59	30.0	31.2	49.6
Example 106
Comparative	2.1	2.1	2.1	680	Yellowish	2.56	20.1	23.3	30.9
Example 107
Comparative	1.9	1.9	1.9	410	Slightly	2.56	6.7	7.2	11.1
Example 108					yellowish
Comparative	1.4	1.4	1.4	1080	Irregularities	2.50	1.0	1.1	4.4
Example 109
Comparative	2.0	2.5	3.1	340	Good	2.56	0.9	1.4	4.1
Example 110

	TABLE 3
		Mass ratio of	Mass ratio of
	Alkali	polyamide (X)/	polyamide (X)/
	compound	alkali compound (A)	master batch (Y) in	P	M
	(A)	in master batch (Y)	resin composition	[μmol/g]	[μmol/g]	M/P
Example 117	AcNa	96/4	98.75/1.25	0.16	6.24	39.0
Example 118	AcNa	96/4	97.5/2.5	0.16	12.66	79.1
Example 119	AcNa	96/4	96.25/3.75	0.16	18.19	113.7
Example 120	AcNa•3H2O	96/4	98.75/1.25	0.16	3.86	24.1
Example 121	AcNa•3H2O	96/4	97.5/2.5	0.16	7.68	48.0
Example 122	AcNa•3H2O	96/4	96.25/3.75	0.16	11.11	69.4
P: Mole concentration of a phosphorus atom contained per 1 gram of the polyamide resin composition
M: Total mole concentration of an alkali metal atom and an alkaline earth metal atom each contained per 1 gram of the polyamide resin composition

	TABLE 4
	Resin pressure average value	Fish eye		Relative	Gel fraction [%]
	[MPa]	number		viscosity	270° C.	290° C.	290° C.
	Immediately			of film	Appearance	of film	72 hr	24 hr	36 hr
	after starting	3 hr	6 hr	[/m2]	of film	(ηr′)	stay	stay	stay
Example 117	2.1	2.1	2.0	300	Good	2.60	7.0	5.0	9.3
Example 118	1.9	1.9	1.9	310	Good	2.57	4.1	2.3	7.6
Example 119	1.5	1.5	1.5	330	Good	2.55	0.3	1.1	3.1
Example 120	2.1	2.1	2.1	300	Good	2.60	10.0	7.9	14.4
Example 121	2.0	2.0	2.0	350	Good	2.55	8.5	8.8	10.1
Example 122	1.9	1.9	1.9	390	Good	2.54	0.5	0.6	5.3

In Comparative Example 101 in which the alkali compound (A) was not added after producing the polyamide, a fish eye number of the film was small at first, but the gel fraction was high, and gels were produced when the excessive thermal history was applied by staying.

In contrast with this, the polyamide resin compositions of the present invention having 0.03 μmol/g or more and less than 0.32 μmol/g of a mole concentration P of a phosphorus atom contained per g of the polyamide resin composition, 2.2 to 26.1 μmol/g of a total mole concentration M of an alkali metal atom and an alkaline earth metal atom each contained per g of the polyamide resin composition and exceeding 5 and 200 or less of M/P have a good color tone and are reduced in a fish eye number in the film, and they have a low gel fraction and produce less gel in the mold processing.

On the other hand, in the polyamide resin compositions prepared in Comparative Examples 102 to 109 in which the values of a mole concentration P of a phosphorus atom, a total mole concentration M of an alkali metal atom and an alkaline earth metal atom and M/P deviated from the ranges described above, the problems of an inferior appearance of the films and production of gels were brought about. Further, in Comparative Example 110 in which sodium hypophosphite as the phosphorus atom-containing compound (B) was used in an excessive amount, sodium hypophosphite was turned into polyphosphoric acid in the mold processing, and it was adsorbed on a filter used in the mold processing to bring about clogging of the filter and elevate the resin pressure, so that a problem of the productivity was brought about.

Production Example 201

(Production of Polyamide (X201))

A reaction vessel having a content volume of 50 liter equipped with a stirrer, a partial condenser, a full condenser, a thermometer, a dropping funnel, a nitrogen introducing tube and a strand die was charged with 15,000 g (102.6 mole) of adipic acid precisely weighed, 432.6 mg (4.082 mmol, 5 ppm in terms of a phosphorus atom concentration in the polyamide) of sodium hypophosphite monohydrate (NaH₂PO₂.H₂O) and 234.3 mg (2.856 mmol, 0.70 in terms of a mole number ratio based on sodium hypophosphite monohydrate) of sodium acetate and sufficiently substituted with nitrogen, and then the vessel was heated up to 170° C. while stirring an inside of the system under a small amount of nitrogen flow. Metaxylylenediamine 13,896 g (102.0 mol) was dropwise added thereto while stirring, and an inside of the system was continuously heated while removing condensation water produced to an outside of the system. After finishing dropwise adding metaxylylenediamine, the internal temperature was controlled to 260° C. to continue the reaction for 40 minutes. Then, an inside of the system was pressurized by nitrogen to take out the polymer from the strand die, and this was pelletized to obtain about 24 kg of polyamide.

Next, a jacket-equipped tumble dryer provided with a nitrogen gas introducing tube, a vacuum line, a vacuum pump and a thermocouple for measuring an inner temperature was charged with the polyamide described above, and an inside of the tumble dryer was sufficiently substituted with nitrogen having a purity of 99% by volume or more while rotating it at a fixed speed. Then, the tumble dryer was heated under nitrogen gas flow, and the pellet temperature was elevated up to 150° C. in about 150 minutes. When the pellet temperature reached 150° C., a pressure in the system was reduced to 1 Torr or less. The temperature was further continued to be elevated, and after the pellet temperature was elevated up to 200° C. in about 70 minutes, the system was maintained at 200° C. for 30 to 45 minutes. Then, a nitrogen gas having a purity of 99% by volume or more was introduced into the system, and the tumble dryer was cooled while rotating to obtain polyamide (X201).

Production Examples 202 to 211

(Production of Polyamides (X202) to (X211))

Polyamides (X202) to (X211) were synthesized in the same manners as in Production Example 201, except that the amounts of sodium hypophosphite monohydrate and sodium acetate were changed to amounts shown in Table 5. In Production Example 210, the amidation reaction in the polymerization was slow, and it was difficult to carry out the polymerization.

The required amounts of polyamide resins necessary for the following examples and comparative examples were secured by repeating the same production.

Production Example 212

(Production of Polyamide Master Batch (Y201))

The polyamide (X211) 4,950 g and sodium acetate trihydrate 82.95 g (anhydride equivalent to 50 g) were molten and kneaded at 260° C. by means of a double shaft extrusion equipment (model: TEM37B, manufactured by Toshiba Machine Co., Ltd.) to obtain a polyamide master batch (Y201). Hydrated moisture of sodium acetate trihydrate was removed in the melt kneading by vacuum ventilation.

Production Examples 213 to 215

(Production of Polyamide Master Batches (Y202) to (Y204))

Polyamide master batches (Y202) to (Y204) were obtained in the same manner as in Production Example 212, except that an amount of sodium acetate trihydrate was changed to amounts shown in Table 6.

	TABLE 5
	In polyamide (X)
		(B)	(C)		P atom	Na metal
Pro-	Poly-	Added	Added	(C)/(B)	concen-	concen-
duction	amide	amount	amount	Mole	tration	tration
Example	(X)	[g]	[g]	ratio	[ppm]	[μmol/gl
201	X201	0.4326	0.2343	0.70	5	0.274
202	X202	0.1557	0.0844	0.70	1.8	0.099
203	X203	0.1990	0.1078	0.70	2.3	0.126
204	X204	0.3028	0.1640	0.70	3.5	0.192
205	X205	0.6921	0.3749	0.70	8	0.439
206	X206	0.4326	0.1674	0.50	5	0.242
207	X207	0.4326	0.2009	0.60	5	0.258
208	X208	0.4326	0.3013	0.90	5	0.307
209	X209	0.4326	0.3348	1.00	5	0.323
210	X210	0.4326	0.4017	1.20	5	0.355
211	X211	0.4326	0.2176	0.65	5	0.266
(B): phosphorus atom-containing compound (NaH2PO2•H2O)
(C): alkali metal compound (CH3COONa)

	TABLE 6
	Composition
	Polyamide (X)	Alkai compound (A) 1)	In master batch (Y)
	Master		Add		Add	AcNa-	Mass ratio of	Na metal	P atom
Production	batch		amount		amount	equivalent	polyamide (X)/	Concentration	Concentration
Example	(Y)	Kind	[g]	Kind	[g]	mass [g]	alkali compound (A) 2)	[μmol/g]	[μmol/g]
212	Y201	X211	4950	AcNa•3H2O	82.95	50	99.0/1.0	122.2	0.160
213	Y202	X211	4900	AcNa•3H2O	165.89	100	98.0/2.0	244.1	0.158
214	Y203	X211	4850	AcNa•3H2O	248.84	150	97.0/3.0	366.0	0.157
215	Y204	X211	4700	AcNa•3H2O	497.67	300	94.0/6.0	731.7	0.152
1) Mass of alkali compound (A) was calculated as an anhydrous salt equivalent mass, when alkali compound (A) is a hydrate salt.
2) Mass ratio of alkali compound (A) in master batch (Y) was calculated by reducing mass of alkali compound (A) to an anhydrous salt equivalent mass, when alkali compound (A) is a hydrate salt.

Example 201

Sodium acetate 3.2 g was added to 20 kg of the polyamide (X201), and the mixture was stirred and mixed to obtain a polyamide resin composition. The polyamide resin composition thus obtained was used to produce a three layer preform comprising a polyester layer/a barrier layer/a polyester layer.

Polyethylene terephthalate (trade name: RT543C, manufactured by Japan Unipet Co., Ltd.) having an intrinsic viscosity of 0.75 (measured at 30° C. in a mixed solvent of phenol/tetrachloroethane=6/4 (mass ratio)) was used for the polyester layer, and a polyamide resin composition described in Table 7 was used for the gas-barrier layer.

The three layer preform has a shape of a whole length: 95 mm, a major diameter: 22 mm and a wall thickness: 4.2 mm, and it was produced by means of an injection molding machine (model: M200, manufactured by Meiki Co., Ltd.) having two injection cylinders and a metal die (four articles molded per shot, manufactured by Kata Systems Company).

The molding conditions of the three layer preform are shown below, and in order to accelerate degradation of the resin, an injection cylinder temperature at a core side (barrier layer side) and a resin flow channel temperature in an inside of the metal die were set to higher levels than usual.

Injection cylinder temperature at a skin side: 280° C.

Injection cylinder temperature at a core side: 290° C.

Resin flow channel temperature in an inside of the metal die: 290° C.

Metal die cooling water temperature: 15° C.

Proportion of the barrier resin in the preform: 5% by mass

Cycle time: 40 seconds

Examples 202 to 214

Multilayer preforms were produced in the same manners as in Example 201, except that the polyamide (X) and sodium acetate were used in kinds and blend amounts shown in Table 7.

Example 215

The polyamide (X211) 19.5 kg and the polyamide master batch (Y201) 0.5 kg were stirred and mixed to obtain a polyamide resin composition. The polyamide resin composition thus obtained was used to produce a multilayer preform.

Examples 216 to 221

Multilayer preforms were produced in the same manners as in Example 215, except that the polyamide master batches (Y) were used in kinds and blend amounts shown in Table 7.

Comparative Examples 201 to 202

Multilayer preforms were produced in the same manner as in Example 201, except that the polyamide (X) and sodium acetate were used in kinds and blend amounts shown in Table 7.

The preform produced in Comparative Example 201 had a good stability but generated a lot of burnt deposits. In Comparative Example 202, the weighing time in the injection molding was long, and the present positions of the barrier layer in the preform were scattered, so that the stable preform could not be obtained.

	TABLE 7
	Properties of polyamide
	Mass ratio of	resin composition	Evaluation of preform
	Composition of polyamide	master batch	Na metal	P atom		Number of		Weigh-
	resin composition	(Y)/polyamide	concentration	concentration	M/P	preform	PFM	ing
	Polyamide (X)	Master batch (Y)	(X) in resin	M	P	mole	having burnt	sta-	time
	Kind	[g]	[g]	Kind	[g]	composition	[μmol/g]	[μmol/g]	[ppm]	ratio	deposits	bility	[sec]
Example 201	X201	20000	3.2	—	0	—	2.23	0.16	4.999	13.9	8	good	5
Example 202	X201	20000	6.6	—	0	—	4.30	0.16	4.998	26.9	5	good	5
Example 203	X201	20000	10.3	—	0	—	6.55	0.16	4.997	40.9	0	good	6
Example 204	X201	20000	21	—	0	—	13.06	0.16	4.995	81.6	3	good	8
Example 205	X201	20000	31.5	—	0	—	19.44	0.16	4.992	121.5	3	good	10
Example 206	X202	20000	18	—	0	—	11.06	0.06	1.798	186.0	2	good	7
Example 207	X203	20000	18	—	0	—	11.09	0.07	2.298	158.4	2	good	7
Example 208	X204	20000	18	—	0	—	11.15	0.11	3.497	101.4	2	good	7
Example 209	X201	20000	18	—	0	—	11.24	0.16	4.996	70.3	1	good	7
Example 210	X205	20000	18	—	0	—	11.40	0.26	7.993	43.8	0	good	7
Example 211	X206	20000	12	—	0	—	7.55	0.16	4.997	47.2	0	good	6
Example 212	X207	20000	12	—	0	—	7.57	0.16	4.997	47.3	0	good	6
Example 213	X208	20000	12	—	0	—	7.62	0.16	4.997	47.6	0	good	6
Example 214	X209	20000	12	—	0	—	7.63	0.16	4.997	47.7	0	good	6
Example 215	X211	19500	0	Y201	500	2.5/97.5	3.31	0.16	4.999	20.7	6	good	4
Example 216	X211	19500	0	Y202	500	2.5/97.5	6.36	0.16	4.998	39.8	4	good	4
Example 217	X211	19500	0	Y203	500	2.5/97.5	9.41	0.16	4.996	58.8	0	good	4
Example 218	X211	19500	0	Y204	500	2.5/97.5	18.55	0.16	4.993	115.9	3	good	4
Example 219	X211	19800	0	Y202	200	1.0/99.0	2.70	0.16	4.999	16.9	7	good	4
Example 220	X211	19000	0	Y202	1000	5.0/95.0	12.46	0.16	4.995	77.9	0	good	4
Example 221	X211	18000	0	Y202	2000	10.0/90.0	24.65	0.16	4.990	154.1	3	good	4
Comparative	X211	20000	0	—	0	—	0.27	0.16	5.000	1.7	20	good	4
Example 201
Comparative	X211	20000	49	—	0	—	30.06	0.16	5.000	187.9	—	in-	30
Example 202												ferior

As apparent from the results obtained in the examples and the comparative examples, the multilayer molded articles of the present invention provided less burnt deposit and had a good productivity.

Production Examples 301 to 315 and Comparative Examples 301 to 305

(Melt Polymerization of Polyamide)

A reaction vessel having a content volume of 50 liter equipped with a stirrer, a partial condenser, a full condenser, a thermometer, a dropping funnel, a nitrogen introducing tube and a strand die was charged with 15,000 g (102.6 mole) of adipic acid precisely weighed, 432.6 mg (4.082 mmol, 5 ppm in terms of a phosphorus atom concentration in the polyamide) of sodium hypophosphite monohydrate (NaH₂PO₂.H₂O) and 206.4 mg (2.516 mmol, 0.62 in terms of a mole number ratio based on sodium hypophosphite monohydrate) of sodium acetate and sufficiently substituted with nitrogen, and then the vessel was heated up to 170° C. while stirring an inside of the system under a small amount of nitrogen flow. Metaxylylenediamine 13,895 g (102.0 mol) was dropwise added thereto while stirring, and an inside of the system was continuously heated while removing condensation water produced to an outside of the system. After finishing dropwise adding metaxylylenediamine, the internal temperature was controlled to 260° C. to continue the reaction for 40 minutes. Then, an inside of the system was pressurized by nitrogen to take out the polymer from the strand die, and this was pelletized to obtain about 24 kg of polyamide.

(Solid Phase Polymerization of Polyamide)

Next, a jacket-equipped tumble dryer provided with a nitrogen gas introducing tube, a vacuum line, a vacuum pump and a thermocouple for measuring an inner temperature was charged with the polyamide described above, and an inside of the tumble dryer was sufficiently substituted with nitrogen having a purity of 99% by volume or more while rotating it at a fixed speed. Then, the tumble dryer was heated under nitrogen gas flow, and the pellet temperature was elevated up to 150° C. in about 150 minutes. When the pellet temperature reached 150° C., a pressure in the system was reduced to 1 Torr or less. The temperature was further continued to be elevated, and after the pellet temperature was elevated up to 200° C. in about 70 minutes, the system was maintained at 200° C. for 30 to 45 minutes. Then, a nitrogen gas having a purity of 99% by volume or more was introduced into the system, and the tumble dryer was cooled while rotating to obtain polyamide (X301).

(Production of Polyamide Master Batches (Y301) to (Y308))

A double shaft extruding equipment (model: TEM37BS, bore diameter: 37 mmφ, manufactured by Toshiba Machine Co., Ltd.) equipped with a strand die was used to supply the polyamide (X301) described above and sodium acetate trihydrate or sodium carbonate decahydrate respectively from different feeders in blend proportions shown in Table 8 to turn the mixture into a strand form by melting and kneading them at an extrusion temperature of 260° C. As shown in Table 8, both of melting temperatures Tm of sodium acetate trihydrate and sodium carbonate decahydrate are 260° C. or less of melt-kneading temperature.

Next, it was cooled in a water-cooled bath and then pelletized by means of a pelletizer. Thereafter, the pellets were dried at 0.1 Torr or less and 140° C. for 8 hours by means of a vacuum dryer to obtain a polyamide master batch (Y301) to (Y308).

The master batch (Y307) in which a total mole concentration m of an alkali metal atom and an alkaline earth metal atom each contained per g of the master batch exceeded 900 μmol/g was heavily reduced in a viscosity, and the pellets could not be molded.

	TABLE 8
	Alkali compound (A)	Mass
Master		Melting	ratio of alkali
batch		temperature	compound (A)/	m
(Y)	Kind	Tm [° C.]	polyamide (X)	[μmol/g]
Y301	AcNa•3H2O	58	0.9/99.1	109.1
Y302	AcNa•3H2O	58	1.2/98.8	145.5
Y303	AcNa•3H2O	58	2.4/97.6	285.1
Y304	AcNa•3H2O	58	3.5/96.5	436.5
Y305	AcNa•3H2O	58	4.6/95.4	582.0
Y306	AcNa•3H2O	58	6.7/93.3	864.2
Y307*	AcNa•3H2O	58	9.8/90.2	—
Y308	Na2CO3•10H2O	34	1.5/98.5	271.2
*The viscosity was low, and the pellets could not be molded.

(Production of Films from Polyamide Resin Compositions)

The prescribed amounts of the polyamide master batch (Y301) to (Y306) or (Y308) and the polyamide (X301) were mixed in a blend proportion shown in Table 9, and then a film was produced by means of a film extrusion equipment comprising a 25 mmφ single shaft extrusion equipment (model: PTM25, manufactured by Plastics Technology Co., Ltd.), a head provided with a filter of 600 mesh and a T die and a receiving equipment equipped with a cooling roll, a fish eye inspection equipment (model: GX70W, manufactured by Mamiya-OP Co., Ltd.) and a reeling device while maintaining an extrusion temperature at 260° C. The polyamide resin composition was extruded in a film form from the extrusion equipment while maintaining a discharge rate of 3 kg/hour, and the receiving velocity was adjusted to obtain a film having a width of 15 cm and a thickness of 50 μm.

	TABLE 9
	Master	Mass ratio of
	batch	master batch (Y)/	P	M
	(Y)	polyamide (X)	[μmol/g]	[μmol/g]	M/P
Example 301	Y302	1.6/98.4	0.03	2.55	85.0
Example 302	Y303	2.0/98.0	0.04	6.29	157.3
Example 303	Y302	1.6/98.4	0.07	2.56	36.6
Example 304	Y304	2.7/97.3	0.07	12.33	176.1
Example 305	Y302	1.6/98.4	0.16	2.59	16.2
Example 306	Y302	2.4/97.6	0.16	3.82	23.9
Example 307	Y302	3.2/96.8	0.16	5.11	31.9
Example 308	Y306	2.7/97.6	0.16	24.33	152.1
Example 309	Y306	2.7/97.3	0.30	24.33	81.1
Example 310	Y308	4.2/95.8	0.30	24.33	81.1
Example 311	Y302	7.7/92.3	0.16	12.20	76.3
Example 312	Y303	4.0/96.0	0.16	12.40	77.5
Example 313	Y304	2.7/97.3	0.16	12.90	80.6
Example 314	Y305	2.0/98.0	0.16	12.20	76.3
Example 315	Y306	1.4/98.6	0.16	12.30	76.9
Comparative	Y301	1.1/98.9	0.16	1.22	7.6
Example 301
Comparative	Y306	4.0/96.0	0.16	34.90	218.1
Example 302
Comparative	Y301	2.2/97.8	0.02	2.34	117.0
Example 303
Comparative	Y306	4.0/96.0	0.30	35.04	116.8
Example 304
Comparative	Y304	2.7/97.3	0.46	12.10	26.3
Example 305
P: Mole concentration of a phosphorus atom contained per 1 gram of the polyamide resin composition
M: Total mole concentration of an alkali metal atom and an alkaline earth metal atom each contained per 1 gram of the polyamide resin composition

	TABLE 10
	Resin pressure average value	Fish eye		Relative	Gel fraction [%]
	[MPa]	number		viscosity	270° C.	290° C.	290° C.
	Immediately			of film	Appearance	of film	72 hr	24 hr	36 hr
	after starting	3 hr	6 hr	[/m2]	of film	(ηr′)	stay	stay	stay
Example 301	2.0	2.0	2.0	270	Good	2.60	14.8	15.6	21.2
Example 302	2.0	2.0	2.0	300	Good	2.52	10.2	13.1	16.9
Example 303	2.1	2.1	2.1	300	Good	2.60	14.1	14.8	20.0
Example 304	2.0	2.0	2.0	390	Good	2.55	1.9	1.2	5.0
Example 305	2.1	2.0	2.0	290	Good	2.60	13.3	14.1	18.9
Example 306	2.1	2.1	2.1	330	Good	2.57	10.1	9.2	15.0
Example 307	2.0	2.0	2.0	400	Good	2.55	6.8	5.1	9.6
Example 308	2.0	2.0	2.0	300	Good	2.55	0.6	0.8	3.3
Example 309	2.0	2.0	2.0	480	Good	2.51	1.9	0.3	3.6
Example 310	2.0	2.0	2.0	480	Good	2.51	1.0	0.1	2.9
Example 311	1.8	1.8	1.8	310	Good	2.46	2.3	2.1	5.5
Example 312	2.0	2.0	2.0	330	Good	2.50	4.1	3.0	6.1
Example 313	2.2	2.1	2.1	350	Good	2.57	3.0	1.9	3.1
Example 314	2.2	2.2	2.2	400	Good	2.57	2.2	3.5	4.5
Example 315	2.3	2.2	2.2	580	Good	2.59	0.3	1.1	3.1
Comparative	2.1	2.1	2.1	310	Good	2.60	27.1	23.2	42.9
Example 301
Comparative	1.9	1.9	1.9	990	Irregularities	2.50	1.4	0.8	2.0
Example 302
Comparative	2.1	2.1	2.1	680	Yellowish	2.56	20.1	23.3	30.9
Example 303
Comparative	1.9	1.9	1.9	1080	Irregularities	2.49	1.0	1.1	4.4
Example 304
Comparative	2.0	2.5	3.1	340	Good	2.56	0.9	1.4	4.1
Example 305

The polyamide resin compositions of the present invention which are obtained by adding the polyamide master batches and which have 0.03 μmol/g or more and less than 0.32 μmol/g of a mole concentration P of a phosphorus atom contained per g of the polyamide resin composition, 2.2 to 26.1 μmol/g of a total mole concentration M of an alkali metal atom and an alkaline earth metal atom each contained per g of the polyamide resin composition and exceeding 5 and 200 or less of M/P have a good color tone and are reduced in a fish eye number in the film, and they have a low gel fraction and produce less gel in the mold processing.

INDUSTRIAL APPLICABILITY

The polyamide resin composition of the present invention is excellent in a gas-barrier property and a transparency and has a good color tone, and in addition thereto, it has less number of fish eyes in the film and a low gel fraction and produces less gel in mold processing. Accordingly, the polyamide resin composition of the present invention is industrially useful as a packaging material, a gasoline-barrier material, a fiber material and the like. Also, the multilayer molded article of the present invention provides less burnt deposit and has a very high industrial value as a multilayer bottle and the like.

Claims

1. A polyamide resin composition comprising a polyamide (X) comprising a diamine unit comprising 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and an alkali compound (A), wherein the following equations (1) to (3) are satisfied:

0.03≦P<0.32  (1);

2.2≦M≦26.1  (2); and

5<M/P≦200  (3),

wherein:

P represents a mole concentration (μmol/g) of a phosphorus atom contained per g of the polyamide resin composition; and

M represents a sum (μmol/g) of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide resin composition by valencies thereof respectively.

2. The polyamide resin composition according to claim 1, wherein the alkali compound (A) is a carboxylate having 10 or less carbon atoms of an alkali metal.

3. The polyamide resin composition according to claim 1, wherein the polyamide (X) is polyamide comprising a diamine unit comprising 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit comprising 70 mol % or more of an adipic acid unit.

4. The polyamide resin composition according to claim 1, wherein the polyamide (X) is polyamide comprising a diamine unit comprising 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit comprising 70 to 99 mol % of an adipic acid unit and 1 to 30 mol % of an isophthalic acid unit.

5. The polyamide resin composition according to claim 1, wherein the polyamide (X) is polyamide comprising a diamine unit comprising 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit comprising 70 mol % or more of a sebacic acid unit.

6. A process for producing the polyamide resin composition according to claim 1, the process comprising:

(a) reacting a diamine comprising 70 mol % or more of metaxylylenediamine and a dicarboxylic acid by polycondensation in the presence of a phosphorus atom-containing compound (B) to obtain the polyamide (X); and

(b) adding the an alkali compound (A) the polyamide (X) to form a polyamide resin composition.

7. The process according to claim 6, wherein in the polycondensation (a) occurs in the presence of the phosphorus atom-containing compound (B) and an alkali metal compound (C).

8. The process according to claim 6, wherein the reacting (b) comprises:

(b1) molting and kneading 90 to 99 parts by mass of the polyamide (X) and 10 to 1 parts by mass of the alkali compound (A) with an extrusion equipment to obtain a polyamide master batch (Y); and

(b2) molting and kneading 0.5 to 20 parts by mass of the polyamide master batch (Y) and 99.5 to 80 parts by mass of the polyamide (X).

9. The process according to any of claim 8, wherein:

the polyamide master batch (Y) is such that a sum of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide master batch (Y) by valencies thereof, respectively, is 12 μmol/g or more and 900 μmol/g or less; and

the alkali compound (A) satisfies the following conditions (i) and (ii): (i) the alkali compound (A) is a carbonate, a hydrogencarbonate or a carboxylate having 10 or less carbon atoms of an alkali metal or an alkaline earth metal; and (ii) a melting temperature Tm of the alkali compound (A) is not higher than a melt-kneading temperature K.

10. A polyamide master batch suitable for the process according to claim 8,

wherein:

the polyamide master batch is obtained by molting and kneading 90 to 99 parts by mass of the polyamide (X) comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and 10 to 1 parts by mass of an alkali compound (A) in the presence of the phosphorus atom-containing compound (B) and an alkali metal compound (C);

the polyamide master batch is such that a sum of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the master batch by valencies thereof, respectively, is 12 μmol/g or more and 900 μmol/g or less; and

the alkali compound (A) satisfies the following conditions (i) and (ii): the alkali compound (A) is a carbonate, a hydrogencarbonate or a carboxylate having 10 or less carbon atoms of an alkali metal or an alkaline earth metal; and (ii) a melting temperature Tm of the alkali compound (A) is not higher than a melt-kneading temperature K.

11. A multilayer molded article, comprising:

an outermost layer;

an innermost layer; and

a gas-barrier layer between the outermost layer and the innermost layer,

wherein:

the outermost layer and the innermost layer are formed from a polyester resin comprising a dicarboxylic acid unit comprising 80 mol % or more of a terephthalic acid unit and a diol unit comprising 80 mol % or more of an ethylene glycol unit; and

the gas-barrier layer is formed from the polyamide resin composition according to claim 1.

12. The multilayer molded article according to claim 11, which is a multilayer bottle obtained by blow-molding a multilayer preform by a hot parison method or a cold parison method.

13. The polyamide resin composition according to claim 2, wherein the polyamide (X) is polyamide comprising a diamine unit comprising 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit comprising 70 mol % or more of an adipic acid unit.

14. The polyamide resin composition according to claim 2, wherein the polyamide (X) is polyamide comprising a diamine unit comprising 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit comprising 70 to 99 mol % of an adipic acid unit and 1 to 30 mol % of an isophthalic acid unit.

15. The polyamide resin composition according to claim 2, wherein the polyamide (X) is polyamide comprising a diamine unit comprising 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit comprising 70 mol % or more of a sebacic acid unit.

16. The process according to claim 7, wherein the reacting (b) comprises:

(b1) molting and kneading 90 to 99 parts by mass of the polyamide (X) and 10 to 1 parts by mass of the alkali compound (A) with an extrusion equipment to obtain a polyamide master batch (Y); and

(b2) molting and kneading 0.5 to 20 parts by mass of the polyamide master batch (Y) and 99.5 to 80 parts by mass of the polyamide (X).

17. The process according to any of claim 16, wherein:

the polyamide master batch (Y) is such that a sum of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the polyamide master batch (Y) by valencies thereof, respectively, is 12 μmol/g or more and 900 μmol/g or less; and

the alkali compound (A) satisfies the following conditions (i) and (ii): (i) the alkali compound (A) is a carbonate, a hydrogencarbonate or a carboxylate having 10 or less carbon atoms of an alkali metal or an alkaline earth metal; and (ii) a melting temperature Tm of the alkali compound (A) is not higher than a melt-kneading temperature K.

18. A polyamide master batch suitable for the process according to claim 9,

wherein:

the polyamide master batch is obtained by molting and kneading 90 to 99 parts by mass of the polyamide (X) comprising a diamine unit containing 70 mol % or more of a metaxylylenediamine unit and a dicarboxylic acid unit and 10 to 1 parts by mass of an alkali compound (A) in the presence of the phosphorus atom-containing compound (B) and an alkali metal compound (C);

the polyamide master batch is such that a sum of values obtained by multiplying a mole concentration of an alkali metal atom and a mole concentration of an alkaline earth metal atom each contained per g of the master batch by valencies thereof, respectively, is 12 μmol/g or more and 900 μmol/g or less; and

the alkali compound (A) satisfies the following conditions (i) and (ii): (i) the alkali compound (A) is a carbonate, a hydrogencarbonate or a carboxylate having 10 or less carbon atoms of an alkali metal or an alkaline earth metal; and (ii) a melting temperature Tm of the alkali compound (A) is not higher than a melt-kneading temperature K.