Patent Description:
Heretofore, attempts have been made to mix different types of resins to obtain mixed resins that can offer characteristics superior to those that are offered by each of the resins alone. For example, a technique is disclosed by the present inventors in the following Patent Literatures <NUM> to <NUM>, in which a polyamide resin and a polyolefin resin are used in combination to obtain a mixed resin having improved characteristics.

<CIT> describes a resin composition comprising a blend of a first resin, a second resin incompatible with the first resin, and a modified elastomer having a reactive group capable of reacting with the first resin, wherein the resin composition has a co-continuous phase structure including a continuous phase A formed of the first resin and a continuous phase B formed of the second resin, and also has a dispersed domain a distributed in the continuous phase A, a finely dispersed subdomain a' distributed in the dispersed domain a, a dispersed domain b distributed in the continuous phase B, and a finely dispersed subdomain b' distributed in the dispersed domain b, the dispersed domain a includes a dispersed domain formed of at least one selected from the group consisting of the second resin and a reaction product of the first resin and the modified elastomer, the dispersed domain b includes a dispersed domain formed of at least one selected from the group consisting of the first resin and the reaction product of the first resin and the modified elastomer, and the finely dispersed subdomain a' and the finely dispersed subdomain b' are each independently a finely dispersed subdomain formed of at least one selected from the group consisting of the first resin, the second resin, the modified elastomer, and the reaction product of the first resin and the modified elastomer.

Patent Literature <NUM> discloses a polymer alloy of a polyamide resin and a polyolefin resin (thermoplastic resin composition) obtained by using, as a compatibilizer, a modified elastomer having a reactive group capable of reacting with the polyamide resin.

Patent Literature <NUM> discloses that a plant-derived polyamide resin can be used as a polyamide resin contained in a polymer alloy of a polyamide resin and a polyolefin resin.

Patent Literature <NUM> discloses a polymer alloy containing a polyamide resin and a polyolefin resin, which has a resin phase-separated structure having a continuous phase, a dispersed phase dispersed in the continuous phase, and a fine dispersed phase further dispersed in the dispersed phase.

Patent Literature <NUM> discloses that a polymer alloy excellent in impact resistance can be obtained by first melt-mixing a polyamide resin and a compatibilizer and then further melt-mixing the obtained mixed resin and a polyolefin resin.

However, according to the above Patent Literatures <NUM> to <NUM>, the present inventors have studied the production and use of these polymer alloys alone, but have not studied the use of these polymer alloys together with other resins.

In light of the above circumstances, it is an object of the present invention to provide a molded body excellent in impact resistance obtained by blending an impact-resistant resin containing a polyamide resin and a polyolefin resin with a polyolefin resin, and a method for producing the same.

The present invention is as follows. A molded body according to claim <NUM> is defined in this claim.

A molded body according to claim <NUM> is the molded body according to claim <NUM>, wherein the thermoplastic resin is a mixture of the first polyolefin resin and an impact-resistant resin containing the second polyolefin resin, the polyamide resin, and the modified elastomer.

A molded body according to claim <NUM> is the molded body according to claim <NUM> or <NUM>, wherein the modified elastomer is an olefin-based thermoplastic elastomer having, as its skeleton, a copolymer of ethylene or propylene and an α-olefin having <NUM> to <NUM> carbon atoms, or a styrene-based thermoplastic elastomer having a styrene skeleton.

A molded body according to claim <NUM> is the molded body according to any one of claims <NUM> to <NUM>, wherein when a total of the polyamide resin and the modified elastomer is <NUM>% by mass, a content of the polyamide resin is <NUM>% by mass or more but <NUM>% by mass or less.

A molded body according to claim <NUM> is the molded body according to any one of claims <NUM> to <NUM>, wherein the dispersed phase (B) has a continuous phase (B<NUM>) containing the polyamide resin and a fine dispersed phase (B<NUM>) dispersed in the continuous phase (B<NUM>) and containing the modified elastomer.

A production method according to claim <NUM> is a method for producing the molded body according to claim <NUM>, including:.

A production method according to claim <NUM> is the molded body production method according to claim <NUM>, wherein the impact-resistant resin has a continuous phase (C) containing the second polyolefin resin and a dispersed phase (B) dispersed in the continuous phase (C) and containing the polyamide resin and the modified elastomer, and
the dispersed phase (B) has a continuous phase (B<NUM>) containing the polyamide resin and a fine dispersed phase (B<NUM>) dispersed in the continuous phase (B<NUM>) and containing the modified elastomer.

A production method according to claim <NUM> is the molded body production method according to claim <NUM> or <NUM>, wherein the first polyolefin resin is a block copolymerized polyolefin resin having an ethylene block as a dispersed phase.

The molded body according to the present invention can achieve excellent impact-resistant characteristics.

When the thermoplastic resin is a mixture of the first polyolefin resin and an impact-resistant resin containing the second polyolefin resin, the polyamide resin, and the modified elastomer, the molded body can achieve particularly excellent impact-resistant characteristics.

When the modified elastomer is an olefin-based thermoplastic elastomer having, as its skeleton, a copolymer of ethylene or propylene and an α-olefin having <NUM> to <NUM> carbon atoms or a styrene-based thermoplastic elastomer having a styrene skeleton, a specific phase structure can be more reliably obtained, and therefore the molded body can offer excellent impact resistance.

When the total of the polyamide resin and the modified elastomer is <NUM>% by mass and the content of the polyamide resin is <NUM>% by mass or more but <NUM>% by mass or less, a specific phase structure can be more stably obtained, and therefore the molded body can offer excellent impact resistance.

When the dispersed phase (B) has a continuous phase (B<NUM>) containing the polyamide resin and a fine dispersed phase (B<NUM>) dispersed in the continuous phase (B<NUM>) and containing the modified elastomer, a multiple phase structure is formed, and therefore the molded body has more excellent impact resistance.

When the first polyolefin resin is a block copolymerized polyolefin resin having an ethylene block as a dispersed phase, and at least part of the ethylene block is aggregated at the interface between the continuous phase (A) and the dispersed phase (B), a multiple phase structure is formed, and therefore the molded body has more excellent impact resistance.

According to the production method of the present invention, the molded body according to the present invention can be reliably obtained which has a continuous phase (A) containing a first polyolefin resin and a second polyolefin resin and a dispersed phase (B) dispersed in the continuous phase (A) and containing a polyamide resin and a modified elastomer.

When the impact-resistant resin has a continuous phase (C) containing the second polyolefin resin and a dispersed phase (B) dispersed in the continuous phase (C) and containing the polyamide resin and the modified elastomer, and the dispersed phase (B) has a continuous phase (B<NUM>) containing the polyamide resin and a fine dispersed phase (B<NUM>) dispersed in the continuous phase (B<NUM>) and containing the modified elastomer, a molded body having a multiple phase structure and excellent impact resistance can be reliably obtained.

When the first polyolefin resin is a block copolymerized polyolefin resin having an ethylene block as a dispersed phase, a molded body can be reliably obtained which has a multiple phase structure in which at least part of the ethylene block is aggregated at the interface between the continuous phase (A) and the dispersed phase (B). That is, a molded body having particularly excellent impact resistance can be reliably obtained.

The particulars shown herein are by way of example and for purposes of illustrative discussion of embodiments of the present invention, and are presented in the cause of providing what is believed to be the most useful and readily understood description of the principles and conceptual aspects of the present invention. In this regard, no attempt is made to show structural details of the present invention in more detail than is necessary for a fundamental understanding of the present invention, and the description taken with the drawings makes apparent to those skilled in the art how the several forms of the present invention may be embodied in practice.

A molded body according to the present invention is defined in claim <NUM>.

The "first polyolefin resin" (hereinafter also simply referred to as a "first polyolefin") is an olefin homopolymer and/or an olefin copolymer. In the molded body, this first polyolefin resin is contained in the continuous phase (A) together with the second polyolefin resin.

An olefin constituting the first polyolefin is not particularly limited, and examples thereof include ethylene, propylene, <NUM>-butene, <NUM>-methyl-<NUM>-butene, <NUM>-pentene, <NUM>-methyl-<NUM>-pentene, <NUM>-methyl-<NUM>-pentene, <NUM>-hexene, and <NUM>-octene. These olefins may be used singly or in combination of two or more of them.

Specific examples of the polyolefin resin include a polyethylene resin, a polypropylene resin, poly-<NUM>-butene, poly-<NUM>-hexene, and poly-<NUM>-methyl-<NUM>-pentene. These polymers may be used singly or in combination of two or more of them. That is, the polyolefin resin may be a mixture of two or more of the above polymers.

Examples of the polyethylene resin include an ethylene homopolymer and a copolymer of ethylene and another olefin. Examples of the latter include an ethylene-<NUM>-butene copolymer, an ethylene-<NUM>-hexene copolymer, an ethylene-<NUM>-octene copolymer, and an ethylene-<NUM>-methyl-<NUM>-pentene copolymer (the content of an ethylene-derived structural unit is <NUM>% or more of the total structural units).

Examples of the polypropylene resin include a propylene homopolymer and a copolymer of propylene and another olefin.

Examples of another olefin constituting the copolymer of propylene and another olefin include the above-mentioned various olefins (except for propylene). Among them, for example, ethylene and <NUM>-butene are preferred. That is, the copolymer of propylene and another olefin is preferably a propylene-ethylene copolymer or a propylene-<NUM>-butene copolymer.

Further, the copolymer of propylene and another olefin may be either a random copolymer or a block copolymer. Among them, a block copolymer is preferred in terms of excellent impact resistance. Particularly, a propylene-ethylene block copolymer having ethylene as another olefin is preferred. This propylene-ethylene block copolymer is a block copolymerized polypropylene having an ethylene block as a dispersed phase. More specifically, the propylene-ethylene block copolymer is a polypropylene resin having a continuous phase composed of homopolypropylene and a dispersed phase present in the continuous phase and containing polyethylene. Such a block copolymerized polypropylene having an ethylene block as a dispersed phase is also called, for example, an impact copolymer, a polypropylene impact copolymer, a heterophasic polypropylene, or a heterophasic block polypropylene. This block copolymerized polypropylene is preferred in terms of excellent impact resistance.

It is to be noted that the content of a propylene-derived structural unit of the copolymer of propylene and another olefin is <NUM>% or more of the total structural units.

The "second polyolefin resin" (hereinafter, also simply referred to as a "second polyolefin") is an olefin homopolymer and/or an olefin copolymer. In the molded body, this second polyolefin resin is contained in the continuous phase (A) together with the first polyolefin resin.

An olefin constituting the second polyolefin is not particularly limited, and examples thereof include the same olefins as mentioned above with reference to the first polyolefin.

The first polyolefin and the second polyolefin are different resins.

When the first polyolefin and the second polyolefin are different resins, the first polyolefin and, optionally, the second polyolefin is a block copolymerized polyolefin resin (e.g., a block copolymerized polypropylene resin) having an ethylene block as a dispersed phase, and the other is a non-block copolymerized polyolefin resin.

In this case, in terms of impact resistance, it is preferred that the first polyolefin be a block copolymerized polypropylene resin having an ethylene block as a dispersed phase and the second polyolefin be a non-block copolymerized polyolefin resin. Further, the non-block copolymerized polyolefin resin is preferably a homopolypropylene resin.

In the above described case where the first polyolefin is a block copolymerized polypropylene resin having an ethylene block as a dispersed phase, and the second polyolefin is a non-block copolymerized polypropylene resin, the molded body has a continuous phase (A) formed of homopolypropylene constituting the first polypropylene resin and the second polypropylene resin, a dispersed phase (B) dispersed in the continuous phase (A) and containing the polyamide resin and the modified elastomer, and a dispersed phase (B') composed of the ethylene block constituting the first polypropylene resin. In addition, at least part of the ethylene block is aggregated at the interface between the continuous phase (A) and the dispersed phase (B). This allows the molded body to offer particularly excellent impact resistance.

The weight-average molecular weight (based on polystyrene standards) of each of the first polyolefin resin and the second polyolefin resin measured by gel permeation chromatography (GPC) is not particularly limited, and may be, for example, <NUM>,<NUM> or more but <NUM>,<NUM> or less, but is preferably <NUM>,<NUM> or more but <NUM>,<NUM> or less, more preferably <NUM>,<NUM> or more but <NUM>,<NUM> or less.

It is to be noted that the first polyolefin resin and the second polyolefin resin are polyolefins that have no affinity for the polyamide resin, which will be described later, and that have no reactive group capable of reacting with the polyamide resin, either. The first and second polyolefin resins are different in this point from an olefin-based component as the modified elastomer that will be described later.

The "polyamide resin" is a polymer having a chain-like skeleton formed by polymerizing a plurality of monomers via amide bonds (-NH-CO-). In the molded body, this polyamide resin is contained in the dispersed phase (B) together with the modified elastomer.

Examples of a monomer constituting the polyamide resin include: amino acids such as <NUM>-aminocaproic acid, <NUM>-aminoundecanoic acid, <NUM>-aminododecanoic acid, and para-aminomethylbenzoic acid; and lactams such as ε-caprolactam, undecane lactam, and ω-lauryllactam. These monomers may be used singly or in combination of two or more of them.

Further, the polyamide resin can be obtained also by copolymerization of a diamine and a dicarboxylic acid. In this case, examples of the diamine as a monomer include: aliphatic diamines such as ethylenediamine, <NUM>,<NUM>-diaminopropane, <NUM>,<NUM>-diaminobutane, <NUM>,<NUM>-diaminohexane, <NUM>,<NUM>-diaminoheptane, <NUM>,<NUM>-diaminooctane, <NUM>,<NUM>-diaminononane, <NUM>,<NUM>-diaminodecane, <NUM>,<NUM>-diaminoundecane, <NUM>,<NUM>-diaminododecane, <NUM>,<NUM>-diaminotridecane, <NUM>,<NUM>-diaminotetradecane, <NUM>,<NUM>-diaminopentadecane, <NUM>,<NUM>-diaminohexadecane, <NUM>,<NUM>-diaminoheptadecane, <NUM>,<NUM>-diaminooctadecane, <NUM>,<NUM>-diaminononadecane, <NUM>,<NUM>-diaminoeicosane, <NUM>-methyl-<NUM>,<NUM>-diaminopentane, and <NUM>-methyl-<NUM>,<NUM>-diaminooctane; alicyclic diamines such as cyclohexanediamine and bis-(<NUM>-aminocyclohexyl) methane; and aromatic diamines such as xylylenediamines (e.g., p-phenylenediamine and m-phenylenediamine). These diamines may be used singly or in combination of two or more of them.

Further, examples of the dicarboxylic acid as a monomer include: aliphatic dicarboxylic acids such as oxalic acid, malonic acid, succinic acid, glutaric acid, adipic acid, pimelic acid, suberic acid, azelaic acid, sebacic acid, undecanedioic acid, dodecanedioic acid, brasylic acid, tetradecanedioic acid, pentadecanedioic acid, and octadecanedioic acid; alicyclic dicarboxylic acids such as cyclohexanedicarboxylic acids; and aromatic dicarboxylic acids such as phthalic acid, terephthalic acid, isophthalic acid, and naphthalene dicarboxylic acid. These dicarboxylic acids may be used singly or in combination of two or more of them.

Specific examples of the polyamide resin include polyamide <NUM>, polyamide <NUM>, polyamide <NUM>, polyamide <NUM>, polyamide <NUM>, polyamide <NUM>, polyamide <NUM>, polyamide 6T, polyamide 6I, polyamide 9T, polyamide M5T, polyamide <NUM>, polyamide <NUM>, polyamide 10T, polyamide MXD6, polyamide 6T/<NUM>, polyamide 6T/6I, polyamide 6T/6I/<NUM>, polyamide 6T/<NUM>-5T, and polyamide 9T/<NUM>-8T. These polyamides may be used singly or in combination of two or more of them.

In the present invention, among the above-described various polyamide resins, plant-derived polyamide resins can be used. Plant-derived polyamide resins are preferred from the viewpoint of environmental protection (particularly from the viewpoint of carbon neutral) because they are resins using monomers derived from plant-derived components such as vegetable oils.

Examples of the plant-derived polyamide resins include polyamide <NUM> (hereinafter, also simply referred to as "PA11"), polyamide <NUM> (hereinafter, also simply referred to as "PA610"), polyamide <NUM> (hereinafter, also simply referred to as "PA612"), polyamide <NUM> (hereinafter, also simply referred to as "PA614"), polyamide <NUM> (hereinafter, also simply referred to as "PA1010"), polyamide <NUM> (hereinafter, also simply referred to as "PA1012"), and polyamide 10T (hereinafter, also simply referred to as "PA10T"). These plant-derived polyamide resins may be used singly or in combination of two or more of them.

Among the above, PA11 has a structure in which monomers having <NUM> carbon atoms are linked via amide bonds. PA11 can be obtained using aminoundecanoic acid derived from castor oil as a monomer. The content of a structural unit derived from the monomer having <NUM> carbon atoms in PA11 is preferably <NUM>% or more or may be <NUM>% of all the structural units of PA11.

PA610 has a structure in which monomers having <NUM> carbon atoms and monomers having <NUM> carbon atoms are linked via amide bonds. PA610 can be obtained using sebacic acid derived from castor oil as a monomer. The total content of a structural unit derived from the monomer having <NUM> carbon atoms and a structural unit derived from the monomer having <NUM> carbon atoms in PA610 is preferably <NUM>% or more or may be <NUM>% of all the structural units of PA610.

PA1010 has a structure in which a diamine having <NUM> carbon atoms and a dicarboxylic acid having <NUM> carbon atoms are copolymerized. PA1010 can be obtained using <NUM>,<NUM>-decanediamine (decamethylenediamine) and sebacic acid, which are derived from castor oil, as monomers. The total content of a structural unit derived from the diamine having <NUM> carbon atoms and a structural unit derived from the dicarboxylic acid having <NUM> carbon atoms in PA <NUM> is preferably <NUM>% or more or may be <NUM>% of all the structural units of PA <NUM><NUM>.

PA614 has a structure in which monomers having <NUM> carbon atoms and monomers having <NUM> carbon atoms are linked via amide bonds. PA614 can be obtained using a plant-derived dicarboxylic acid having <NUM> carbon atoms as a monomer. The total content of a structural unit derived from the monomer having <NUM> carbon atoms and a structural unit derived from the monomer having <NUM> carbon atoms in PA614 is preferably <NUM>% or more or may be <NUM>% of all the structural units of PA614.

PA10T has a structure in which a diamine having <NUM> carbon atoms and terephthalic acid are linked via amide bonds. PA10T can be obtained using <NUM>,<NUM>-decanediamine (decamethylenediamine) derived from castor oil as a monomer. The total content of a structural unit derived from the diamine having <NUM> carbon atoms and a structural unit derived from terephthalic acid is preferably <NUM>% or more or may be <NUM>% of all the structural units of PA10T.

Among the above five plant-derived polyamide resins, PA11 is superior to the other four plant-derived polyamide resins in terms of low water absorbability, low specific gravity, and high biomass degree.

Polyamide <NUM> is inferior to PA11 in water absorption rate, chemical resistance, and impact strength, but is excellent in heat resistance (melting point) and rigidity (strength). Further, polyamide <NUM> is superior to polyamide <NUM> or polyamide <NUM> in terms of low water absorbability and excellent size stability, and therefore can be used as an alternative to polyamide <NUM> or polyamide <NUM>.

Polyamide <NUM> is superior to PA11 in heat resistance and rigidity. Further, the biomass degree of polyamide <NUM> is comparable to that of PA11, and therefore polyamide <NUM> can be used for parts required to have higher durability.

Polyamide 10T has an aromatic ring in its molecular framework, and therefore has a higher melting point and higher rigidity than polyamide <NUM>. Therefore, polyamide 10T can be used in harsh environments (parts required to have heat resistance, parts on which a force is to be exerted).

The "modified elastomer" is an elastomer having a reactive group that reacts with the polyamide resin. In the molded body, this modified elastomer is contained in the dispersed phase (B) together with the polyamide resin.

Further, the modified elastomer preferably has an affinity for the second polyolefin resin. More specifically, the modified elastomer preferably has compatibilizing effect on the polyamide resin and the second polyolefin resin. In other words, the modified elastomer is preferably a compatibilizer for the polyamide resin and the second polyolefin resin.

Examples of the reactive group include an acid anhydride group (-CO-O-OC-), a carboxyl group (-COOH), an epoxy group {-C<NUM>O (a three-membered ring structure composed of two carbon atoms and one oxygen atom)}, an oxazoline group (-C<NUM>H<NUM>NO), and an isocyanate group (-NCO). These reactive groups may be used singly or in combination of two or more of them.

The amount of modification of the modified elastomer is not limited, and the modified elastomer only needs to have one or more reactive groups per molecule. Further, the modified elastomer preferably has <NUM> or more but <NUM> or less reactive groups, more preferably <NUM> or more but <NUM> or less reactive groups, particularly preferably <NUM> or more but <NUM> or less reactive groups per molecule.

Examples of the modified elastomer include: a polymer using any monomer capable of introducing a reactive group (a modified elastomer obtained by polymerization using a monomer capable of introducing a reactive group); an oxidative degradation product of any polymer (a modified elastomer having a reactive group formed by oxidative degradation), and a graft polymer obtained by graft polymerization of an organic acid on any polymer (a modified elastomer having a reactive group introduced by graft polymerization of an organic acid). These modified elastomers may be used singly or in combination of two or more of them. These modified elastomers may be used singly or in combination of two or more of them.

Examples of the monomer capable of introducing a reactive group include: a monomer having a polymerizable unsaturated bond and an acid anhydride group; a monomer having a polymerizable unsaturated bond and a carboxyl group; and a monomer having a polymerizable unsaturated bond and an epoxy group.

Specific examples thereof include: acid anhydrides such as maleic anhydride, itaconic anhydride, succinic anhydride, glutaric anhydride, adipic anhydride, citraconic anhydride, tetrahydrophthalic anhydride, butenyl succinic anhydride; and carboxylic acids such as maleic acid, itaconic acid, fumaric acid, acrylic acid, and methacrylic acid. These compounds may be used singly or in combination of two or more of them. Among these compounds, an acid anhydride is preferred, maleic anhydride and itaconic anhydride are more preferred, and maleic anhydride is particularly preferred.

Further, the type of resin constituting the skeleton of the modified elastomer (hereinafter, referred to as a "skeletal resin") is not particularly limited, and various thermoplastic resins can be used. As this skeletal resin, one or two or more of the various resins mentioned above as examples of the polyolefin resin can be used.

In addition, the skeletal resin may be an olefin-based thermoplastic elastomer or a styrene-based thermoplastic elastomer. These thermoplastic elastomers may be used singly or in combination of two or more of them.

Examples of the olefin-based thermoplastic elastomer include copolymers of two or more of olefins.

Examples of the olefins include ethylene, propylene, and α-olefins having <NUM> to <NUM> carbon atoms. Examples of the α-olefin having <NUM> to <NUM> carbon atoms include <NUM>-butene, <NUM>-methyl-<NUM>-butene, <NUM>-pentene, <NUM>-methyl-<NUM>-pentene, <NUM>-methyl-<NUM>-pentene, <NUM>-hexene, and <NUM>-octene. Among such olefin-based thermoplastic elastomers, a copolymer of ethylene and an α-olefin having <NUM> to <NUM> carbon atoms and a copolymer of propylene and an α-olefin having <NUM> to <NUM> carbon atoms are preferred.

Specific examples of the copolymer of ethylene and an α-olefin having <NUM> to <NUM> carbon atoms include ethylene-propylene copolymers (EPR), ethylene-<NUM>-butene copolymers (EBR), ethylene-<NUM>-pentene copolymers, and ethylene-<NUM>-octene copolymers (EOR). Specific examples of the copolymer of propylene and an α-olefin having <NUM> to <NUM> carbon atoms include propylene-<NUM>-butene copolymers (PBR), propylene-<NUM>-pentene copolymers, and propylene-<NUM>-octene copolymers (POR). These copolymers may be used singly or in combination of two or more of them.

On the other hand, examples of the styrene-based thermoplastic elastomer include: a block copolymer of a styrene-based compound and a conjugated diene compound; and a hydrogenated product thereof.

Examples of the styrene-based compound include: styrene; alkylstyrenes such as α-methylstyrene, p-methylstyrene, and p-t-butylstyrene; p-methoxystyrene; and vinylnaphthalene. These styrene-based compounds may be used singly or in combination of two or more of them.

Examples of the conjugated diene compound include butadiene, isoprene, piperylene, methylpentadiene, phenylbutadiene, <NUM>,<NUM>-dimethyl-<NUM>,<NUM>-hexadiene, and <NUM>,<NUM>-diethyl-<NUM>,<NUM>-octadiene. These conjugated diene compounds may be used singly or in combination of two or more of them.

Specific examples of the styrene-based thermoplastic elastomer include styrene-butadiene-styrene copolymers (SBS), styrene-isoprene-styrene copolymers (SIS), styrene-ethylene/butylene-styrene copolymers (SEBS), and styrene-ethylene/propylene-styrene copolymers (SEPS). These styrene-based thermoplastic elastomers may be used singly or in combination of two or more of them. Among them, SEBS is preferred.

The molecular weight of the modified elastomer is not particularly limited, but the weight-average molecular weight of the modified elastomer is preferably <NUM>,<NUM> or more but <NUM>,<NUM> or less, more preferably <NUM>,<NUM> or more but <NUM>,<NUM> or less, particularly preferably <NUM>,<NUM> or more but <NUM>,<NUM> or less. It is to be noted that the weight-average molecular weight is measured by a GPC method (based on polystyrene standards).

The molded body may contain, in addition to the first polyolefin resin, the second polyolefin resin, the polyamide resin, and the modified elastomer, various additives such as another thermoplastic resin, a flame retardant, a flame retardant aid, a filler, a colorant, an antimicrobial agent, and an antistatic agent. These additives may be used singly or in combination of two or more of them.

Examples of another thermoplastic resin include polyester-based resins (polybutylene terephthalate, polyethylene terephthalate, polycarbonate, polybutylene succinate, polyethylene succinate, polylactic acid). These thermoplastic resins may be used singly or in combination of two or more of them.

Examples of the flame retardant include halogen-based flame retardants (halogenated aromatic compounds), phosphorus-based flame retardants (e.g., nitrogen-containing phosphate compounds, phosphoric acid esters), nitrogen-based flame retardants (e.g., guanidine, triazine, melamine, and derivatives thereof), inorganic flame retardants (e.g., metal hydroxides), boron-based flame retardants, silicone-based flame retardants, sulfur-based flame retardants, and red phosphorus-based flame retardants. These flame retardants may be used singly or in combination of two or more of them.

Examples of the flame retardant aid include various antimony compounds, metal compounds containing zinc, metal compounds containing bismuth, magnesium hydroxide, and clayey silicate. These flame retardant aids may be used singly or in combination of two or more of them.

Examples of the filler include: glass components (e.g., glass fibers, glass beads, glass flakes); silica; inorganic fibers (glass fibers, alumina fibers, carbon fibers); graphite; silicate compounds (e.g., calcium silicate, aluminum silicate, kaolin, talc, clay); metal oxides (e.g., iron oxide, titanium oxide, zinc oxide, antimony oxide, alumina); carbonates and sulfates of metals such as calcium, magnesium, and zinc; and organic fibers (e.g., aromatic polyester fibers, aromatic polyamide fibers, fluororesin fibers, polyimide fibers, vegetable fibers). These fillers may be used singly or in combination of two or more of them.

Examples of the colorant include pigments and dyes. These colorants may be used singly or in combination of two or more of them.

In the molded body, the first polyolefin resin and the second polyolefin resin form a continuous phase (A). Further, the polyamide resin and the modified elastomer form a dispersed phase (B). The dispersed phase (B) is dispersed in the continuous phase (A). This phase structure can be obtained by molding a thermoplastic resin that is a mixture of the first polyolefin resin and an impact-resistant resin containing the second polyolefin resin, the polyamide resin, and the modified elastomer.

Further, in the molded body, the polyamide resin constituting the dispersed phase (B), which is composed of the polyamide resin and the modified elastomer, forms a continuous phase (B<NUM>) in the dispersed phase (B), and at least the modified elastomer out of the polyamide resin and the modified elastomer can form a fine dispersed phase (B<NUM>) in the dispersed phase (B). When having such a multiple phase structure in which a fine dispersed phase (B<NUM>) is present in a dispersed phase (B), the molded body can have more excellent impact resistance.

Further, when the first polyolefin resin is a block copolymerized polyolefin resin having an ethylene block as a dispersed phase, at least part of the ethylene block constituting the block copolymerized polyolefin resin can be aggregated at the interface between the continuous phase (A) and the dispersed phase (B) in the molded body. Also when having such a phase structure, the molded body can have more excellent impact resistance.

The size of the dispersed phase (B) contained in the continuous phase (A) of the molded body is not particularly limited, but the average diameter (average particle diameter) of the dispersed phase (B) is preferably <NUM> or less, more preferably <NUM> or more but <NUM> or less, even more preferably <NUM> or more but <NUM> or less. The average diameter of the dispersed phase (B) is the average of maximum lengths (nm) of <NUM> particles of the dispersed phase (B) randomly selected on an image obtained using an electron microscope.

The size of the fine dispersed phase (B<NUM>) contained in the dispersed phase (B) of the molded body is not particularly limited, but the average diameter (average particle diameter) of the fine dispersed phase (B<NUM>) is preferably <NUM> or more but <NUM> or less, more preferably <NUM> or more but <NUM> or less, even more preferably <NUM> or more but <NUM> or less, particularly preferably <NUM> or more but <NUM> or less. The average diameter of the fine dispersed phase (B<NUM>) is the average of maximum lengths (nm) of <NUM> particles of the fine dispersed phase (B<NUM>) randomly selected on an image obtained using an electron microscope.

When the total of the continuous phase (A) and the dispersed phase (B) in the molded body is <NUM>% by mass, the content of the dispersed phase (B) is <NUM>% by mass or less. More specifically, when the total amount of the first polyolefin resin and the second polyolefin resin is defined as WA, the total amount of the polyamide resin and the modified elastomer is defined as WB, and the total of WA and WB is <NUM>% by mass, the ratio of WB is usually <NUM>% by mass or less. When the ratio of Wa is within the above range, the molded body can offer excellent impact resistance and an excellent balance between rigidity and moldability. The ratio of WB is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less, particularly preferably <NUM>% by mass or more but <NUM>% by mass or less.

Further, the content of each of the first polyolefin resin and the second polyolefin resin is not particularly limited. However, when the total of the first polyolefin resin and the second polyolefin resin is <NUM>% by mass, the content of the second polyolefin resin is preferably <NUM>% by mass or less. The content of the second polyolefin resin is more preferably <NUM>% by mass or more but <NUM>% by mass or less, particularly preferably <NUM>% by mass or more but <NUM>% by mass or less.

In addition, when the total of the polyamide resin and the modified elastomer is <NUM>% by mass, the content of the polyamide resin may be <NUM>% by mass or more but <NUM>% by mass or less. When the content of the polyamide resin is within the above range, a phase structure can be obtained in which the second polyolefin resin forms a continuous phase (A) and the polyamide resin forms a dispersed phase (B). This makes it possible to obtain a thermoplastic resin composition and a molded body that offer excellent impact resistance and excellent rigidity. The content of the polyamide resin is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less, even more preferably <NUM>% by mass or more but <NUM>% by mass or less, even more preferably <NUM>% by mass or more but <NUM>% by mass or less, particularly preferably <NUM>% by mass or more but <NUM>% by mass or less, more particularly preferably <NUM>% by mass or more but <NUM>% by mass or less. When the content of the polyamide resin is within the above range, the polyamide resin and the modified elastomer can be dispersed as smaller particles of the dispersed phase (B) in the continuous phase (A). Further, the amount of the polyamide resin, which has a large specific gravity, to be used can be reduced to reduce the specific gravity of the molded body. This allows the molded body to have excellent impact resistance and rigidity while being lightweight.

Further, as described above, since the content of the polyamide resin can be reduced while the mechanical characteristics are well maintained, the molded body can have relaxing appearance with low surface luster. Therefore, the molded body can be applied to exterior and interior materials that are directly visually recognized, and can offer excellent design flexibility.

Further, when the total of the first polyolefin resin, the second polyolefin resin, the polyamide resin, and the modified elastomer is <NUM>% by mass, the content of the polyamide resin may be <NUM>% by mass or more but <NUM>% by mass or less. The content of the polyamide resin is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less.

Further, when the total of the first polyolefin resin, the second polyolefin resin, the polyamide resin, and the modified elastomer is <NUM>% by mass, the content of the modified elastomer may be <NUM>% by mass or more but <NUM>% by mass or less. When the content of the modified elastomer is within the above range, the molded body can offer excellent impact resistance and excellent rigidity. The content of the modified elastomer is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less.

The specific gravity of the molded body is not particularly limited, but may usually be <NUM> or less. When the molded body has a polyamide resin content of <NUM>% by mass or more but <NUM>% by mass or less, a polypropylene resin content of <NUM>% by mass or more but <NUM>% by mass or less, and a maleic anhydride-modified olefin-based thermoplastic elastomer content of <NUM>% by mass or more but <NUM>% by mass or less, the specific gravity of the molded body may particularly be <NUM> or more but <NUM> or less, more particularly <NUM> or more but <NUM> or less. That is, even when having the same specific gravity as a polyethylene resin and a polypropylene resin, the molded body can offer much more excellent impact resistance and rigidity than these resins.

The shape, size, thickness, etc. of the molded body are not particularly limited, and its application is not particularly limited, either.

The molded body is used as various articles for use in vehicles such as automobiles, railway vehicles (general railway vehicles), aircraft fuselages (general fuselages), and boats and ships/hulls (general hulls), and bicycles (general bicycles).

Among them, articles for use in automobiles include exterior parts, interior parts, engine parts, and electrical parts. Specific examples of the exterior parts for automobiles include roof rails, fenders, fender liners, garnishes, bumpers, door panels, roof panels, hood panels, trunk lids, fuel lids, door mirror stays, spoilers, hood louvers, wheel covers, wheel caps, grill apron cover frames, lamp bezels, door handles (pull handles), door moldings, rear finishers, wipers, engine under covers, floor under covers, rocker moldings, cowl louvers, and cowls (motorcycles).

Specific examples of the interior parts for automobiles include: trim parts such as door trim base materials (FR, RR, BACK), pockets, arm rests, switch bases, decorative panels, ornament panels, EA materials, speaker grills, and quarter trim base materials; pillar garnishes; cowl side garnishes (cowl side trims); seat parts such as shields, back boards, dynamic dampers, and side air bag peripheral parts; instrument panel parts such as center clusters, registers, center boxes (doors), glove doors, cup holders, and air bag peripheral parts; center consoles; overhead consoles; sun visors; deck boards (luggage boards); under trays; package trays; high mount stop lamp covers; CRS covers; seat side garnishes; scuff plates; room lamps; assist grips; safety belt parts; register blades; washer levers; window regulator handles; knobs of window regulator handles; and passing light levers.

Specific examples of the engine parts for automobiles include alternator terminals, alternator connectors, IC regulators, potentiometer bases for light dimmers, exhaust gas valves, fuel pipes, cooling pipes, brake pipes, wiper pipes, exhaust pipes, intake pipes, hoses, tubes, air intake nozzle snorkels, intake manifolds, fuel pumps, engine cooling water joints, carburetor main bodies, carburetor spacers, exhaust gas sensors, cooling water sensors, oil temperature sensors, brake pad wear sensors, throttle position sensors, crankshaft position sensors, air flow meters, brake pad wear sensors, brake pistons, solenoid bobbins, engine oil filters, and ignitor cases, and torque control levers.

Specific examples of the electrical parts for automobiles include battery peripheral parts, air conditioner thermostats, hot air flow control valves, brush holders for radiator motors, water pump impellers, turbine vanes, wiper motor-related parts, distributors, starter switches, starter relays, transmission wire harnesses, window washer nozzles, air conditioner panel switch boards, fuel-related electromagnetic valve coils, various connectors such as wire harness connectors, SMJ connectors, PCB connectors, door grommet connectors, and fuse connectors, horn terminals, electrical component insulating plates, step motor rotors, lamp sockets, lamp reflectors, lamp housings, cleaner cases, filter cases, and power trains.

Further, the molded body is used also as various articles for use in applications other than the above vehicles. Specific examples thereof include: industrial materials such as ropes, spun-bonded fabrics, polishing brushes, industrial brushes, filters, transport containers, trays, transport trolleys, and other general material;.

Other examples of the molded body include pellets formed into various shapes.

A method for producing a molded body according to the present invention is a method for producing the above-described molded body, and includes a molded body raw material preparing step and a molding step.

According to this method, a necessary impact-resistant resin is previously formed, and a mixture of the impact-resistant resin and the first polyolefin resin is subjected to molding, which makes it possible to reduce the heat history of the first polyolefin resin. More specifically, the molded body can be obtained by applying a thermal load to the first polyolefin resin only once during molding, while the heat histories of the polyamide resin, the modified elastomer, and the second polyolefin resin are accumulated in proportion to the number of times of melt-kneading. The molded body having a continuous phase (A) and a dispersed phase (B) can be obtained even by such a production method.

The "molded body raw material preparing step" is a step in which the first polyolefin resin and an impact-resistant resin, which is obtained by melt-kneading the second polyolefin resin and a melt-kneaded product of the polyamide resin and the modified elastomer, are mixed to obtain a molded body raw material.

In this method, a molded body raw material is obtained by blending a previously-formed impact-resistant resin with the first polyolefin resin. More specifically, a molded body raw material can be obtained by, for example, dry-blending pellets made of a previously-obtained impact-resistant resin and pellets made of the first polyolefin resin.

The above melt-kneaded product is a thermoplastic resin composition obtained by melt-kneading the polyamide resin and the modified elastomer. Examples of each of the polyamide resin and the modified elastomer that can be used at this time are the same as those mentioned above.

The melt-kneaded product can be obtained by melt-kneading both the resins so that when the total of the polyamide resin and the modified elastomer is <NUM>% by mass, the blending ratio of the polyamide resin is <NUM>% by mass or more but <NUM>% by mass or less. This makes it possible, when the melt-kneaded product and the second polyolefin resin are mixed, to obtain an impact-resistant resin in which the polyamide resin is dispersed in the second polyolefin resin. More specifically, the impact-resistant resin can have a phase structure in which a continuous phase (C) containing the second polyolefin resin is formed, and a dispersed phase (B) containing the polyamide resin and the modified elastomer is dispersed in the continuous phase (C). Further, a multiple phase structure can be obtained in which the dispersed phase (B) has a continuous phase (B<NUM>) containing the polyamide resin and a fine dispersed phase (B<NUM>) dispersed in the continuous phase (B<NUM>) and containing the modified elastomer.

The blending ratio of the polyamide resin is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less, even more preferably <NUM>% by mass or more but <NUM>% by mass or less, even more preferably <NUM>% by mass or more but <NUM>% by mass or less, particularly preferably <NUM>% by mass or more but <NUM>% by mass or less, more particularly preferably <NUM>% by mass or more but <NUM>% by mass or less. When the blending ratio of the polyamide resin is within the above range, an impact-resistant resin can be obtained in which the polyamide resin is dispersed as smaller particles in the second polyolefin resin.

It is to be noted that from the viewpoint of obtaining a polyamide resin rich-type impact-resistant resin whose polyamide resin content is <NUM>% by mass or more, the blending ratio of the polyamide resin may be <NUM>% by mass or more but <NUM>% by mass or less when the total of the polyamide resin and the modified elastomer is <NUM>% by mass.

A kneading method used to obtain the meld-kneaded product is not particularly limited. The kneaded product can be obtained by, for example, using a kneading device such as an extruder (e.g. a single-screw extruder or a twin-screw extruder), a kneader, or a mixer (e.g., a high-speed flow mixer, a paddle mixer, or a ribbon mixer). These devices may be used singly or in combination of two or more of them. When two or more devices are used, they may be operated either continuously or batch-wise. Further, all the components of the kneaded product may be mixed at a time or may be mixed by adding them in several batches (multistage addition).

Further, the kneading temperature at which the melt-kneaded product is obtained is not particularly limited as long as melt-kneading can be performed, and the kneading temperature can be appropriately adjusted according to the type of each of the components. In particular, it is preferred that all the resins be kneaded in a molten state. More specifically, the kneading temperature may be <NUM> to <NUM>, and is preferably <NUM> to <NUM>, more preferably <NUM> to <NUM>.

The above-described impact-resistant resin is a thermoplastic resin composition obtained by melt-kneading the second polyolefin resin and the above-described melt-kneaded product. Examples of the second polyolefin resin that can be used at this time are the same as those described above.

This impact-resistant resin can be obtained by melt-kneading both the resins so that when the total of the second polyolefin resin and the above-described melt-kneaded product is <NUM>% by mass, the blending ratio of the second polyolefin resin is <NUM>% by mass or more but <NUM>% by mass or less. This makes it possible to disperse the polyamide resin in the second polyolefin resin. More specifically, the impact-resistant resin can have a phase structure in which a continuous phase (C) containing the second polyolefin resin is formed, and a dispersed phase (B) containing the polyamide resin and the modified elastomer is dispersed in the continuous phase (C). Further, a multiple phase structure can be obtained in which the dispersed phase (B) has a continuous phase (B<NUM>) containing the polyamide resin and a fine dispersed phase (B<NUM>) dispersed in the continuous phase (B<NUM>) and containing the modified elastomer.

The blending ratio of the second polyolefin resin is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less. When the blending ratio of the second polyolefin resin is within the above range, an impact-resistant resin can be obtained in which the polyamide resin is dispersed as smaller particles in the second polyolefin resin.

A kneading method used to obtain the impact-resistant resin is not particularly limited, and the same device, operation mode, and kneading temperature as described above with reference to a case where the above-described melt-kneaded product is obtained may be used.

When the total of the second polyolefin resin and the polyamide resin is <NUM>% by mass, the content of the polyamide resin may be <NUM>% by mass or less (usually, <NUM>% by mass or more). The content of the polyamide resin is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less, even more preferably <NUM>% by mass or more but <NUM>% by mass or less, even still more preferably <NUM>% by mass or more but <NUM>% by mass or less, particularly preferably <NUM>% by mass or more but <NUM>% by mass or less, more particularly preferably <NUM>% by mass or more but <NUM>% by mass or less, even more particularly preferably <NUM>% by mass or more but <NUM>% by mass or less.

Further, when the total of the second polyolefin resin, the polyamide resin, and the modified elastomer is <NUM>% by mass, the content of the polyamide resin may be <NUM>% by mass or more but <NUM>% by mass or less. The content of the polyamide resin is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less, even more preferably <NUM>% by mass or more but <NUM>% by mass or less, even still more preferably <NUM>% by mass or more but <NUM>% by mass or less, particularly preferably <NUM>% by mass or more but <NUM>% by mass or less.

Further, when the total of the second polyolefin resin, the polyamide resin, and the modified elastomer is <NUM>% by mass, the content of the modified elastomer may be <NUM>% by mass or more but <NUM>% by mass or less. The content of the modified elastomer is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less, even more preferably <NUM>% by mass or more but <NUM>% by mass or less, even still more preferably <NUM>% by mass or more but <NUM>% by mass or less, particularly preferably <NUM>% by mass or more but <NUM>% by mass or less, more particularly preferably <NUM>% by mass or more but <NUM>% by mass or less.

The above-described molded body raw material is a thermoplastic resin mixture obtained by mixing the first polyolefin resin and the above-described impact-resistant resin. Examples of the first polyolefin resin that can be used at this time are the same as those mentioned above.

The molded body raw material can be obtained by mixing both the resins so that when the total of the first polyolefin resin and the impact-resistant resin is <NUM>% by mass, the blending ratio of the first polyolefin resin is <NUM>% by mass or more but <NUM>% by mass or less. This makes it possible to obtain a molded body raw material in which the heat history load of first polyolefin resin has been reduced.

The blending ratio of the first polyolefin resin is preferably <NUM>% by mass or more but <NUM>% by mass or less, more preferably <NUM>% by mass or more but <NUM>% by mass or less.

Further, as described above, the molded body obtained by this method may contain, in addition to the first polyolefin resin, the second polyolefin resin, the polyamide resin, and the modified elastomer, various additives such as a flame retardant, a frame retardant aid, a filler, a colorant, an antimicrobial agent, and an antistatic agent. When these additives are added to the molded body, the impact-resistant resin can be used as a carrier that carries these additives.

The above-described "molding step" is a step in which the molded body raw material obtained in the molded body raw material preparing step is molded to obtain a molded body.

A molding method to be used in this molding step is not particularly limited, and any molding method may be used. Examples of the molding method include injection molding, extrusion molding (sheet extrusion, profile extrusion), T-die molding, blow molding, injection blow molding, inflation molding, blow molding, vacuum molding, compression molding, press molding, stamping molding, and transfer molding. These molding methods may be used singly or in combination of two or more of them.

It is to be noted that according to this method, a molded body can be obtained by molding a thermoplastic resin, the molded body having a continuous phase (A) containing a first polyolefin resin and a second polyolefin resin and a dispersed phase (B) dispersed in the continuous phase (A) and containing a polyamide resin and a modified elastomer, wherein the dispersed phase (B) is composed of a melt-kneaded product obtained by melt-kneading the polyamide resin and the modified elastomer having a reactive group that reacts with the polyamide resin, and wherein when a total of the continuous phase (A) and the dispersed phase (B) is <NUM>% by mass, a content of the dispersed phase (B) is <NUM>% by mass or less, and when a total of the first polyolefin resin and the second polyolefin resin is <NUM>% by mass, a content of the second polyolefin resin is <NUM>% by mass or less. The molded body obtained by the above method can offer significantly excellent impact resistance while well maintaining rigidity that the first polyolefin originally has. Further, a molded body in which the heat history of the first polyolefin resin has been reduced can be obtained by blending, as the first polyolefin resin, part of a polyolefin to be used as compared to when the whole polyolefin is blended from the beginning. That is, a molded body can be obtained by molding, as the above-described thermoplastic resin, a mixture of the first polyolefin resin and an impact-resistant resin containing the second polyolefin resin, the polyamide resin, and the modified elastomer.

However, at the time of filing the present application, it is impossible to directly specify the property that the heat history of the first polyolefin resin is lower than that of the second polyolefin resin. Even if possible, it takes too much cost and time to specify such a property even with current analytical techniques, and therefore there are unpractical circumstances in light of the necessity of promptness etc., due to the nature of patent application.

Hereinafter, the present invention will be specifically described with reference to examples.

[<NUM>] An impact-resistant resin was prepared by the following procedure. The impact-resistant resin contained <NUM>% by mass of a second polyolefin, <NUM>% by mass of a polyamide resin, and <NUM>% by mass of a modified elastomer per <NUM>% of its total mass.

Pellets of the following polyamide resin and pellets of the following modified elastomer were dry-blended, then fed into a twin-screw melt-kneading extruder (manufactured by TECHNOVEL CORPORATION, screw diameter: <NUM>, LID = <NUM>), and melt-kneaded under conditions of a kneading temperature of <NUM>, an extrusion speed of <NUM>/hr, and a screw rotation speed of <NUM> rpm. The thus obtained melt-kneaded product was pelletized by a pelletizer to obtain pellets of the melt-kneaded product.

The pellets of the molten mixture obtained in the above (<NUM>) and pellets of the following second polyolefin resin were dry-blended, then fed into a twin-screw melt-kneading extruder (manufactured by TECHNOVEL CORPORATION, screw diameter: <NUM>, LID = <NUM>), and mixed under conditions of a kneading temperature of <NUM>, an extrusion speed of <NUM>/hr, and a screw rotation speed of <NUM> rpm. The thus obtained impact-resistant resin was pelletized by a pelletizer to obtain pellets of the impact-resistant resin.

A molded body containing <NUM>% by mass of a first polyolefin and <NUM>% by mass of an impact resistant-resin per <NUM>% of its total mass (Example <NUM>), a molded body containing <NUM>% by mass of a first polyolefin and <NUM>% by mass of an impact-resistant resin per <NUM>% of its total mass (Example <NUM>), and a molded body containing <NUM>% by mass of a first polyolefin and <NUM>% by mass of an impact-resistant resin per <NUM>% of its total mass (Example <NUM>) were each produced by the following procedure.

The pellets of the impact-resistant resin obtained in the above [<NUM>](<NUM>) and pellets of the following first polyolefin resin (<NUM>) were dry-blended to obtain a molded body raw material. The obtained molded body raw material was fed into a hopper of an injection molding machine (manufactured by NISSEI PLASTIC INDUSTRIAL CO. , <NUM>-ton injection molding machine) and injection-molded under injection conditions of a set temperature of <NUM> and a mold temperature of <NUM> to obtain test specimens for measuring physical properties.

A molded body containing <NUM>% by mass of a first polyolefin and <NUM>% by mass of an impact-resistant resin per <NUM>% of its total mass (Example <NUM>), a molded body containing <NUM>% by mass of a first polyolefin and <NUM>% by mass of an impact-resistant resin per <NUM>% of its total mass (Example <NUM>), and a molded body containing <NUM>% by mass of a first polyolefin and <NUM>% by mass of an impact-resistant resin per <NUM>% of its total mass (Example <NUM>) were each produced by the following procedure.

The following polyolefin resin (which was the same as the first polyolefin resin (<NUM>) used for the molded bodies of Examples <NUM> to <NUM>) was fed into a hopper of an injection molding machine (manufactured by NISSEI PLASTIC INDUSTRIAL CO. , <NUM>-ton injection molding machine) and injection-molded under injection conditions of a set temperature of <NUM> and a mold temperature of <NUM> to obtain test specimens for measuring physical properties.

Pellets of the following impact resistance-imparting agent conventionally used to impart impact resistance and pellets of the following polyolefin resin were dry-blended to obtain a molded body raw material, and the molded body raw material was fed into a hopper of an injection molding machine (manufactured by NISSEI PLASTIC INDUSTRIAL CO. , <NUM>-ton injection molding machine) and injection-molded under injection conditions of a set temperature of <NUM> and a mold temperature of <NUM> to obtain test specimens for measuring physical properties.

Measurement of Charpy impact strength was performed in accordance with JIS K <NUM>-<NUM> using each of the specimens for evaluation of Examples <NUM> to <NUM> and Comparative Examples <NUM> to <NUM> obtained in the above [<NUM>]. The results of the measurement are shown in Table <NUM> and Table <NUM>. It is to be noted that in the measurement of Charpy impact strength, impact strength was measured at a temperature of <NUM> by an edgewise test method using a specimen having a notch (type A).

A sample cut out from each of the test specimens of Examples <NUM> to <NUM> and Comparative Examples <NUM> to <NUM> that had been subjected to the measurement of Charpy impact strength described above in (<NUM>) was embedded in a resin. Then, the sample was trimmed and cut in a cross section using an ultramicrotome with a diamond knife and subjected to steam dyeing with a metal oxide. An ultrathin section sample was taken from the obtained cross section after dyeing and observed with a transmission electron microscope (TEM, manufactured by Hitachi High-Technologies Corporation, Model "HT7700") to observe a phase structure. The results of the observation are shown in Table <NUM> and Table <NUM>.

It is to be noted that an image obtained from the sample of Example <NUM> is shown in <FIG>. As shown in <FIG>, a continuous phase (A) containing the first polyolefin resin and the second polyolefin resin, a dispersed phase (B) dispersed in the continuous phase (A) and containing the polyamide resin and the modified elastomer, a continuous phase (B<NUM>) containing the polyamide resin, a fine dispersed phase (B<NUM>) dispersed in the continuous phase (B<NUM>) and containing the modified elastomer, and an aggregate phase (D) in which an ethylene block of the first polyolefin resin is aggregated at the interface between the continuous phase (A) and the dispersed phase (B) were observed.

It is to be noted that the aggregate phase (D) contains not only the ethylene block of the first polyolefin resin but also the modified elastomer.

Measurement of flexural modulus was performed in accordance with JIS K <NUM> using the test specimens for evaluation of Examples <NUM> to <NUM> and Comparative Examples <NUM> to <NUM> obtained in the above [<NUM>]. The results of the measurement are shown in Table <NUM> and Table <NUM>. It is to be noted that the measurement of flexural modulus was performed by applying a load at a speed of <NUM>/min from an action point (curvature radius: <NUM>) located in the middle of the two points while supporting each of the test specimens at two points (curvature radius: <NUM>) whose distance (L) is <NUM>.

A graph of the correlation between the Charpy impact strength and the flexural modulus is shown in <FIG>.

As can be seen from the results shown in Tables <NUM> and <NUM> and <FIG>, when <NUM>% by mass of the conventionally-used impact resistance-imparting agent was added (Comparative Example <NUM>) to improve the impact resistance of the first polyolefin (Comparative Example <NUM>), the Charpy impact strength was improved by <NUM>%, whereas the Charpy impact strength of the molded body according to the present invention produced by the method according to the present invention containing <NUM>% by mass of the impact-resistant resin (Example <NUM>) was improved by <NUM>%. This reveals that even when the amount of the impact-resistant resin added is small, addition of the impact-resistant resin is significantly effective at imparting impact resistance. In addition, when <NUM>% by mass of the conventionally-used impact resistance-imparting agent was added (Comparative Example <NUM>), the flexural modulus was reduced by <NUM>%, whereas a reduction in the flexural modulus of the molded body according to the present invention produced by the method according to the present invention containing <NUM>% by mass of the impact-resistant resin (Example <NUM>) was suppressed to <NUM>%. This reveals that a reduction in rigidity can be extremely suppressed while significantly high impact resistance is achieved. This tendency was consistently observed in all the Examples <NUM> to <NUM>. Further, the tendency was consistently observed also in all the Examples <NUM> to <NUM>. This reveals that the effect can be exhibited irrespective of the type of the first polyolefin.

Further, the result shown in <FIG> reveals that when a block copolymerized polyolefin resin having an ethylene block as a dispersed phase is used as the first polyolefin resin, at least part of the ethylene block (EPR) is aggregated at the interface between the continuous phase (A) and the dispersed phase (B). It is considered that such aggregation results in more excellent impact resistance.

Claim 1:
A molded body obtained by molding a thermoplastic resin, comprising:
a continuous phase (A) containing a first polyolefin resin and a second polyolefin resin; and
a dispersed phase (B) dispersed in the continuous phase (A) and containing a polyamide resin and a modified elastomer, wherein
the dispersed phase (B) is composed of a melt-kneaded product of the polyamide resin and the modified elastomer having a reactive group that reacts with the polyamide resin, and wherein
when a total of the continuous phase (A) and the dispersed phase (B) is <NUM>% by mass, a content of the dispersed phase (B) is <NUM>% by mass or less, and
when a total of the first polyolefin resin and the second polyolefin resin is <NUM>% by mass, a content of the second polyolefin resin is <NUM>% by mass or less, and the first polyolefin resin and the second polyolefin resin are different,
wherein the first polyolefin resin is a block copolymerized polyolefin resin having an ethylene block as a dispersed phase, and at least part of the ethylene block is aggregated at an interface between the continuous phase (A) and the dispersed phase (B).