JPWO2015072500A1 - Molded body and method for producing the same - Google Patents

Abstract

It is an object to provide a molded body containing PBT having excellent heat resistance and transparency. A molded body obtained from a sheet, wherein the molded body is a layer mainly composed of polybutylene terephthalate (hereinafter referred to as PBT) (hereinafter referred to as A layer) and a layer mainly composed of polyester other than PBT. (Hereinafter referred to as B layer), and in the molded body, the A layer is located on at least one surface and satisfies the following (1) and (2). (1) The GTG fraction of the A layer of the molded body is 0.6 or more and 1 or less. (2) The relative crystallinity of the B layer of the molded body is 0% or more and 5% or less.

Description

  The present invention relates to a molded article excellent in transparency and heat resistance, and a method for producing the same.

  Polybutylene terephthalate (hereinafter sometimes abbreviated as PBT) is one of the five major general-purpose engineering plastics, and has excellent mechanical properties, electrical properties, chemical resistance, and heat resistance due to its high crystallinity. Are widely used as various electrical and electronic equipment parts, interior / exterior parts for vehicles such as automobiles, trains and trains, and other general industrial products. In addition, a transparent PBT sheet in an amorphous state is characterized by maintaining transparency even when subjected to a crystallization treatment by a heat treatment at a glass transition temperature or higher. In addition to the heat resistance derived from the transparency and crystallinity of PBT, it is noted that the price is relatively low compared to other engineering plastics, and polyethylene terephthalate (hereinafter abbreviated as PET), which is another general-purpose plastic. In combination with the above, the practical application as a container requiring transparency and heat resistance, such as a molded container for food and a cup lid for beverage, has been studied. As such an example, Patent Document 1 and Patent Document 2 propose a transparent heat-resistant container obtained by thermoforming a sheet made of a blend of PET and PBT. Patent Document 3 and Patent Document 4 refer to a laminated sheet of PBT and PET and a molded container comprising the same.

JP-A-4-212830 Japanese Patent Laid-Open No. 2004-197066 Japanese Patent Laid-Open No. 3-189149 JP-A-4-070333

  However, in the methods described in Patent Document 1 and Patent Document 2, the characteristics derived from the crystallinity inherent in PBT cannot be sufficiently exhibited due to the decrease in crystallinity due to blending with PET, and in terms of practicality. There was a problem of poor heat resistance. On the other hand, the methods described in Patent Document 3 and Patent Document 4 also do not have sufficient heat resistance.

In order to solve the above problems, the present invention has the following configuration. That is:
1) A molded body obtained from a sheet,
The molded body has a layer (hereinafter referred to as “A layer”) containing polybutylene terephthalate (hereinafter referred to as “PBT”) as a main component, and a layer (hereinafter referred to as “B layer”) whose main component is a polyester other than PBT. ,
In the molded body, the A layer is located on at least one surface,
A molded article satisfying the following (1) and (2).

  (1) The GTG fraction of the A layer of the molded body is 0.6 or more and 1 or less.

(2) The relative crystallinity of the B layer of the molded body is 0% or more and 5% or less.
2) The melting point of the B layer of the molded body is higher than the melting point of the A layer of the molded body,
The molded product according to 1) above, wherein the B layer of the molded product has a difference (ΔTcg) between the cold crystallization temperature (Tc) and the glass transition temperature (Tg) of 35 ° C. or higher.
3) The molded body according to 1) or 2), wherein the B layer of the molded body is composed of a layer containing polyethylene terephthalate (hereinafter referred to as PET) as a main component.
4) The molded product according to any one of 1) to 3), wherein the molded product satisfies the following (1) and / or (2).

  (1) The heat shrinkage rate of the molded body at 100 ° C. is 0% or more and 7% or less.

(2) The Charpy impact strength at −20 ° C. of the molded body is 0.4 MJ / m ² or more.
5) The laminate according to any one of 1) to 4) above, wherein the lamination ratio “total thickness of layer A” / “total thickness of layer B” is a ratio of 1/15 to 1/2. Molded body.
6) A method for producing a molded body having a step of preheating a sheet (hereinafter referred to as a preheating step) and a step of forming a sheet (hereinafter referred to as a molding step) in this order,
The sheet has an A layer and a B layer, and in the sheet, the A layer is located on at least one surface,
The molding according to any one of 1) to 5) above, wherein the sheet temperature at the end of the preheating in the preheating step is “melting point of sheet A layer−20” ° C. or more and “melting point of sheet A layer + 20” ° C. or less. Body manufacturing method.
7) In the preheating step, the average temperature increase rate from when the sheet temperature becomes “Tc-30 of the B layer of the sheet” ° C. until the end of the preheating is 20 ° C./second or more in 6) The manufacturing method of the molded object of description.

  According to the present invention, a molded article having heat resistance and excellent transparency is provided. Moreover, the manufacturing method which provides the molded object which has heat resistance and was excellent also in transparency is provided.

  The molded body in the present invention refers to a structure having a three-dimensional shape such as a lid shape, a tray shape, or a cup shape. The shape of the molded body is not particularly limited as long as it is a three-dimensional shape structure, and preferably includes a rectangular container or a cylindrical container having a polygonal shape on the bottom surface, such as a tray, a cup, a case, and The thing which has the shape of those cover materials is mentioned. Further, the shape of the molded product of the present invention is not particularly limited as described above, but it is used for display bottles of beverage vending machines, and other various packaging products such as shape retainers such as blister packs used for display and packaging of products. Various industrial materials, such as a molded object and a surface material, can be mentioned preferably.

  And the molded object of this invention is obtained from a sheet | seat.

  Furthermore, the molded product of the present invention has a layer containing PBT as a main component (hereinafter referred to as A layer) and a layer containing polyester other than PBT as a main component (hereinafter referred to as B layer). , A layer is located on at least one surface. Here, the layer containing PBT as a main component means that PBT is contained in an amount of 50.1% by mass to 100% by mass with respect to 100% by mass of all components of the A layer. Moreover, the layer which has polyester other than PBT as a main component means that 50.1 mass% or more and 100 mass% or less of specific polyesters other than PBT are contained in 100 mass% of all the components of B layer. That is, when the B layer contains a plurality of polyesters other than PBT, when the B layer pays attention to one specific type of polyester, the specific one type of polyester is reduced to 50. It means containing 1 mass% or more and 100 mass% or less. In addition, the kind here is decided by the composition.

  In the present invention, PBT means that terephthalic acid component is contained in an amount of 80 mol% or more and 100 mol% or less in a total of 100 mol% of dicarboxylic acid components, and 80 mol of 1,4-butanediol component in a total of 100 mol% of diol components. % Or more and 100 mol% or less polyester.

  Examples of dicarboxylic acid components that can be used as copolymerization components in PBT include, for example, isophthalic acid component, orthophthalic acid component, naphthalenedicarboxylic acid component, diphenylcarboxylic acid component, diphenylsulfone dicarboxylic acid component, diphenoxyethanedicarboxylic acid component, 5-sodium Sulfoisophthalic acid component, aromatic dicarboxylic acid component such as phthalic acid component, oxalic acid component, succinic acid component, eicoic acid component, adipic acid component, sebacic acid component, dimer acid component, dodecanedioic acid component, maleic acid component, fumaric acid Examples thereof include aliphatic dicarboxylic acid components such as components, aliphatic dicarboxylic acid components such as cyclohexane dicarboxylic acid components, trimellitic acid components, and polyfunctional acid components such as pyromellitic acid components.

  Examples of diol components that can be used as copolymerization components in PBT include, for example, ethylene glycol components, propanediol components, butanediol components, pentanediol components, hexanediol components, neopentyl glycol components, and triethylene glycol components. And aromatic glycol components such as bisphenol A component and bisphenol S component, diethylene glycol component, and polytetramethylene glycol component.

  The PBT may contain a plurality of these dicarboxylic acid components and / or diol components.

Among these, considering both the heat resistance and the moldability, PBT which is the main component of the A layer is preferably any of the following (A) to (D).
(A) A PBT homopolymer containing no copolymerization component.
(B) When the copolymer component is only a dicarboxylic acid component, PBT in which the copolymer component exceeds 0 mol% and is 20 mol% or less in the total 100 mol% of the dicarboxylic acid component.
(C) When the copolymer component is only a diol component, PBT in which the copolymer component exceeds 0 mol% and is 20 mol% or less in the total 100 mol% of the diol component.
(D) When the copolymer component is contained in both the dicarboxylic acid component and the diol component, the copolymer component is added to 200 mol%, which is the sum of 100 mol% of the dicarboxylic acid component and 100 mol% of the diol component. PBT whose total is more than 0 mol% and not more than 20 mol%.

  By using any PBT of (A) to (D) as a main component of the A layer, the order of the PBT is maintained, so that the GTG fraction of the A layer of the molded body described later is 0.6 or more. It becomes easy to make it 1 or less.

  The A layer in the present invention can also contain other thermoplastic resins as long as PBT is the main component, and polyesters other than PBT are suitably selected as the other thermoplastic resins. Among polyesters other than PBT, polyesters that are completely compatible with PBT, have a lower melting point than PBT, or have no melting point are preferable. Here, the term “compatible” refers to a material having only one melting point when DSC measurement is performed on a molten mixture of PBT and another polyester. The melting point of the polyester alone and the presence or absence thereof as well as the melting point of the molten mixture can be confirmed by the same method as the measurement conditions for the melting point of the molded body described later.

  Examples of the polyester other than PBT contained in the A layer include at least selected from the group consisting of polyethylene terephthalate, polyethylene terephthalate / isophthalate, polytrimethylene terephthalate / isophthalate, and poly (ethylene / cyclohexylene-dimethylene) terephthalate. One is preferably used.

  The content of the thermoplastic resin other than PBT in the A layer is preferably 0% by mass or more and 49.9% by mass or less with respect to 100% by mass of all components of the A layer.

  In the present invention, the polyester other than PBT, which is the main component of the B layer, is a polymer containing an ester bond in a repeating unit constituting the polymer, and is a polymer excluding the aforementioned PBT. Among them, aliphatic polyesters and aromatic polyesters other than PBT are preferably selected.

  Examples of the aliphatic polyester that is a polyester other than PBT include polymers composed of hydroxycarboxylic acid and lactone, polycondensates of diol and dicarboxylic acid, and copolymers thereof.

  Examples of the polymer comprising hydroxycarboxylic acid or lactone include polyglycolic acid, poly-L-lactic acid, poly-D-lactic acid, polypropionic acid, polyhydroxybutyric acid, polycaprolactone, and the like.

  Polycondensates of diol and dicarboxylic acid include polybutylene succinate, poly (butylene succinate / butylene adipate), poly (butylene adipate / butylene terephthalate), poly (3-hydroxybutyrate / 3-hydroxyhexanoate) , Etc.

  Among these, poly-L-lactic acid or a copolyester thereof is preferred when the polyester other than PBT is an aliphatic polyester because it is derived from biomass, has biodegradability, and is relatively inexpensive. .

  Examples of aromatic polyesters other than PBT include at least one acid component selected from terephthalic acid, 2,6-naphthalenedicarboxylic acid, isophthalic acid, ethylene glycol, propylene glycol, butylene glycol, and hexylene glycol. Or what is obtained by polycondensation with at least 1 sort (s) of diol components chosen from polyalkylene glycols, such as polyethyleneglycol and polytetramethyleneglycol, specifically, polypropylene terephthalate (PPT), polyethylene terephthalate ( PET), polyhexylene terephthalate (PHT), polyethylene naphthalate (PBN), polybutylene naphthalate (PBN), poly (1,4-cyclohexylenedimethylene terephthalate) Over G) other such as polyethylene isophthalate-terephthalate (PET / I), poly (ethylene / 1,4-cyclohexylene dimethylene), and the like copolymerized polyester such as.

  Among these, as an aromatic polyester that is a polyester other than PBT, it can be obtained at a relatively low cost, and the interlaminar adhesion between the A layer and the B layer and the reuse of scraps generated during film formation and molding of the sheet are considered. Is preferably PET or a copolyester thereof highly compatible with PBT.

  In the B layer of the molded article of the present invention, the polyester other than PBT is preferably at least one polyester selected from polyesters such as the above-described aliphatic polyesters or aromatic polyesters. The B layer in the present invention contains one kind of polyester other than PBT as a main component and may further contain other polyester. Furthermore, the B layer in the present invention may contain other thermoplastic resins as long as polyester other than PBT is the main component.

  In the molded product of the present invention, it is important that the GTG fraction of the A layer of the molded product is 0.6 or more and 1 or less. Here, G and T indicate specific steric structures of PBT in the A layer, where G is an abbreviation for Gauche structure and T is an abbreviation for trans structure. By setting the GTG fraction to be 0.6 or more and 1 or less, it becomes possible to obtain a molded body having practical heat resistance. The GTG fraction of the A layer of the molded body is preferably 0.65 or more, and more preferably 0.7 or more. Further, the GTG fraction is preferably 0.9 or less, and more preferably 0.8 or less.

  In order to set the GTG fraction of the A layer of the molded body to 0.6 or more and 1 or less, for example, as described later, as the PBT that is the main component of the A layer, In the method for producing a molded body having the preheating step and the molding step in this order, the method is to set the sheet temperature at the end of preheating to “melting point of sheet A layer −20” ° C. or more and “melting point of sheet A layer +20” ° C. or less. Can be mentioned.

  In the molded body of the present invention, it is important that the relative crystallinity of the B layer of the molded body is 0% or more and 5% or less because transparency can be imparted to the molded body. The relative crystallinity of the B layer of the molded product can be measured by DSC described later. Many polyesters are known to form a three-dimensional crystal with a spherical structure called a spherulite with thermal crystallization from an amorphous state. When it reaches the wavelength of visible light, there is a problem that light scattering occurs and transparency is lost. Polyester that does not form spherulites by crystallization from an amorphous state, such as special polylactic acid having a stereocomplex crystal, or a crystal nucleating agent that can make the spherulite size smaller than the wavelength of visible light In the polyester to be contained, the above-described problem of transparency reduction due to the spherulites is solved, but these polyesters and crystal nucleating agents are generally expensive and are not preferable in terms of raw material costs. For this reason, when a polyester having the property of forming a spherulite of a size larger than visible light, such as polylactic acid or PET, is used as the main component of the B layer, the relative crystallinity is 0% or more. It is important to set it to 5% or less. The relative crystallinity of the B layer of the molded body is more preferably 0% or more and 4% or less, and further preferably 0% or more and 3% or less.

  In order to set the relative crystallinity of the B layer of the molded body to 0% or more and 5% or less, for example, as described later, the melting point of the B layer of the molded body is higher than the melting point of the A layer of the molded body. About the B layer of a molded object, the method of making the difference ((DELTA) Tcg) of the cold crystallization temperature (Tc) and glass transition temperature (Tg) into 35 degreeC or more, and the manufacturing method of the molded object which has a preheating process and a formation process in this order In the method, the sheet temperature at the end of preheating may be “the melting point of the A layer of the sheet−20 ° C.” or more and “the melting point of the A layer of the sheet + 20” ° C. or less.

  In the molded product of the present invention, when the melting point of the B layer of the molded product is higher than the melting point of the A layer of the molded product, the difference between the cold crystallization temperature (Tc) and the glass transition temperature (Tg) of the B layer of the molded product. (ΔTcg) is preferably 35 ° C. or higher. The melting point of the B layer of the molded body is higher than the melting point of the A layer of the molded body, and the difference (ΔTcg) between the cold crystallization temperature (Tc) and the glass transition temperature (Tg) of the B layer of the molded body is 35 ° C. or more. If it exists, it will become easy to control the relative crystallinity degree of B layer of a molded object to 0% or more and 5% or less, and as a result, it will become easy to provide transparency to the molded object of this invention. ΔTcg of the B layer of the molded body is more preferably 55 ° C. or more, and further preferably 65 ° C. The ΔTcg of the B layer of the molded body is preferably as large as possible from the viewpoint of suppressing the crystallization of the B layer, but the upper limit is considered to be 110 ° C. considering that the crystallization during the molding is substantially completely suppressed. It is done.

  In addition, as a method of making the melting point of the B layer of the molded body higher than the melting point of the A layer of the molded body and setting the ΔTcg of the B layer of the molded body to 35 ° C. or more, for example, suitable as the main component of the B layer For example, a method of selecting a suitable polyester (appropriate composition and appropriate polymerization degree), a method of incorporating a crosslinking agent or an amorphous polyester in the B layer, and the like. Considering the cost, polyethylene terephthalate or its copolyester is selected as the polyester as the main component of the B layer, and those having a ΔTcg of 35 ° C. or more in the DSC measurement of these polyesters alone are the main components of the B layer. It is preferable to select it as a component.

  Here, the melting point of the A layer of the molded body, the melting point of the B layer of the molded body, the cold crystallization temperature Tc, and the glass transition temperature Tg mean values obtained by measuring the molded body using DSC. To do. Similarly, the melting point of the A layer of the sheet, the glass transition temperature Tg, the melting point of the B layer of the sheet, the cold crystallization temperature Tc, and the glass transition temperature Tg can also be obtained by measuring the sheet using DSC. Mean value. These measurements shall be performed according to the method described in the measurement method section.

  The molded body of the present invention has an A layer mainly containing PBT and a B layer mainly containing polyester other than PBT, and it is important that the A layer is located on at least one surface. Therefore, as the configuration of the molded body, it is sufficient that the A layer is positioned on at least one surface. For example, a two-layer configuration of A layer / B layer, a two-type three-layer configuration of A layer / B layer / A layer, A layer / B layer / A layer / B layer and A layer / B layer / A layer / B layer / A layer can also be used. However, considering the manufacturing cost and problems such as curling during storage of the molded product, the configuration of the molded product is preferably a two-layer / three-layer configuration of A layer / B layer / A layer.

  Since the molded product of the present invention is a molded product obtained from a sheet, the sheet as the material of the molded product of the present invention is also a layer A mainly composed of PBT and a polyester mainly composed of polyester other than PBT. The layer A is preferably located on at least one surface. Therefore, as a preferable sheet configuration, the A layer may be positioned on at least one surface. For example, a two-layer configuration of A layer / B layer, a two-type three-layer configuration of A layer / B layer / A layer, A layer / B layer / A layer / B layer and A layer / B layer / A layer / B layer / A layer can also be used. However, considering the manufacturing cost and problems such as curling during sheet storage, the sheet configuration is preferably a two-layer / three-layer configuration of A layer / B layer / A layer.

The thickness of the sheet that is the material of the molded body of the present invention is not particularly limited, but is preferably 50 μm or more and 2000 μm or less, more preferably 100 to 1000 μm, and still more preferably 150 to 500 μm.
The sheet used as the material of the molded body of the present invention preferably contains 5 to 80% of reused (collected) raw material with respect to the entire sheet in order to reduce the production cost of the sheet. Here, the recycled (collected) raw material is a used sheet or a sheet that has not become a product for some reason, is cut into small pieces, made into flakes, and used again as a raw material for the B layer. Say.

  Further, the lamination ratio of the sheet and the molded body that are the material of the molded body of the present invention is not particularly limited. However, in consideration of the moldability of the sheet, “total thickness of layer A” / “thickness of layer B” Is preferably a ratio of 1/15 to 1/2, more preferably 1/10 to 1 / 2.5, and even more preferably 1/8 to 1/3. Here, the “total thickness of the A layer” means the thickness of the A layer when only one A layer is present, and when two or more A layers are present, It means the sum of thickness. “Total thickness of layer B” has the same meaning as layer A.

  It is preferable that the sheet used as the material of the molded body of the present invention is non-oriented in consideration of the moldability. Here, the term “non-orientation” means that the plane orientation coefficient measured by the method described later is in the range of 0.00 to 0.05. The smaller the plane orientation coefficient, the better the moldability and the better. Therefore, the sheet orientation coefficient of the sheet used as the material of the molded body of the present invention is more preferably 0.00 to 0.03, and 0.00 to 0.01. Particularly preferred.

  Moreover, when using the molded object of this invention as a transparent container, it is preferable that a haze is 5% or less. Haze is closely related to light transmission being blocked by surface roughness and voids and spherulites present in the molded body. Among them, haze is greatly influenced by crystallization of the B layer, and the molded body. By setting the relative crystallinity of the B layer to 5% or less, the haze of the molded product can be set to 5% or less. The haze is more preferably 4% or less, and still more preferably 3% or less. On the other hand, the lower limit of haze is 0.1% considering that there are factors other than crystallinity that inhibit light transmission.

  When the molded body of the present invention is used for a container for heating in a range or the like, the heat shrinkage rate at 100 ° C. is preferably 0% or more and 7% or less, more preferably 0% or more and 5% or less. By setting the heat shrinkage rate at 100 ° C. within this range, it is preferable because a molded body with small deformation can be obtained during range heating. Here, the heat shrinkage rate of the molded body is a heat shrinkage rate obtained by a method described later. In order to set the heat shrinkage rate at 100 ° C. of the molded body to 0% or more and 7% or less, for example, as a PBT that is a main component of the A layer, a method using the PBT of the above-described preferred mode, a preheating step, and molding In the manufacturing method of the molded body having the steps in this order, a method of setting the sheet temperature at the end of preheating to “the melting point of the A layer of the sheet−20” ° C. or more and “the melting point of the A layer of the sheet + 20” ° C. or less. it can.

Further, the molded body of the present invention, such as preferably Charpy impact strength 0.4 mJ / ^{m 2} or more at -20 ° C. The time used for the chilled vessel, 0.5 mJ / ^{m 2} or more preferably, 0.7 mJ / m ² or more is more preferable. Setting the Charpy impact strength at −20 ° C. within this range is preferable because breakage such as cracking of the container is unlikely to occur during refrigerated transportation such as when used as a chilled container. The Charpy impact strength at −20 ° C. of the molded body is preferably as high as possible from the above viewpoint, but the upper limit is considered to be 2.0 MJ / m ² from the cutability of the molded body portion after molding during continuous molding. In order to set the Charpy impact strength at −20 ° C. of the molded body to 0.4 MJ / m ² or more, for example, as a PBT that is a main component of the A layer, a method of using the PBT in the above-described preferred mode, or a preheating step And a method for producing a molded body having molding steps in this order, wherein the sheet temperature at the end of preheating is “the melting point of the A layer of the sheet−20” ° C. or more and “the melting point of the A layer of the sheet + 20” ° C. or less. be able to.

  Although the manufacturing method of the molded object in this invention is not specifically limited, The manufacturing of the molded object which has the process (henceforth a preheating process) which preheats a sheet | seat, and the process (henceforth a molding process) which shape | molds a sheet | seat in this order. The method is preferred. Thus, the manufacturing method of the molded object which has a preheating process and a formation process in this order is hereafter called a thermoforming method. Examples of such a manufacturing method include various molding methods such as vacuum molding, vacuum / pressure forming, plug assist molding, straight molding, free drawing molding, plug and ring molding, skeleton molding, and the like. .

  In the various molding methods described above, the preheating step includes an indirect heating method and a hot plate direct heating method. The indirect heating method is a method in which the sheet is preheated by a heating device installed at a position away from the sheet. The hot plate direct heating method is a method in which the sheet is preheated by contacting the sheet and the hot plate. In the preheating step in the method for producing a molded body of the present invention, either an indirect heating method or a hot plate direct heating method can be preferably used, but an indirect heating method is more preferable.

  In the method for producing a molded body of the present invention, the sheet has an A layer and a B layer, and in such a sheet, the A layer is located on at least one surface, and the sheet temperature at the end of preheating in the preheating step is “ The melting point of the A layer of the sheet is preferably −20 ”° C. or higher and“ the melting point of the A layer of the sheet + 20 ”° C. or lower. Here, the sheet temperature refers to the value of the sheet surface detected by a temperature detector such as an infrared radiation thermometer installed at a certain distance from the sheet in the indirect heating method. In the production of a molded body, the sheet temperature to be reached by preheating is usually determined in advance. During the preheating, the transition of the sheet temperature is measured in real time by the temperature detector, and the sheet temperature is When the sheet temperature to be reached is reached, it is preferable to end the preheating step and move to the forming step within 2 seconds. In the method for producing a molded body of the present invention, the sheet temperature to be reached is set as the sheet temperature at the end of preheating.

  In the present invention, the sheet temperature at the end of preheating in the preheating step is set to “melting point of sheet A layer—20” ° C. or more and “melting point of sheet A layer + 20” ° C. or less, so that The fraction became 0.6 or more and 1 or less. It is considered that this is because the molecular mobility of PBT in the A layer is improved and the formation of the three-dimensional structure has advanced, so that a molded body having rigidity even at high temperatures can be obtained. Since the formation of a structure having a GTG fraction of 0.6 or more and 1 or less is closely related to molecular mobility, the melting of the PBT crystal proceeds in earnest “the melting point of the A layer of the sheet + 20” Up to ℃, the temperature at the end of preheating and the GTG fraction are in a proportional relationship, and the sheet temperature at the end of preheating is equal to or higher than the "melting point of the A layer of the sheet" in that the GTG fraction is a higher value. The melting point of the A layer of the sheet + 10 ”° C. or lower is more preferable, and the melting point of the A layer of the sheet + 10 ° C. or higher is more preferable.

  Further, in the present invention, the sheet temperature at the end of preheating in the preheating step is set to “melting point of sheet A layer −20” ° C. or more and “melting point of sheet A layer +20” ° C. or less, thereby forming distortion during molding. It is possible to suppress the occurrence of the above, and it becomes possible to obtain a heat-resistant molded body in which shrinkage is suppressed even at high temperatures.

  Further, in the present invention, when the melting point of the B layer of the sheet is not more than the melting point of the A layer of the sheet (melting point: about 225 ° C.), the sheet temperature at the end of the preheating is “melting point of the A layer of the sheet −20” ° C. or more. By setting the melting point of the A layer of the sheet to 20 ° C. or less, even if the polyester as the main component of the B layer forms crystals during the preheating, the melting becomes higher than the melting point of the polyester at the end of the preheating. . Therefore, the relative crystallinity of the B layer of the finally obtained molded product can be 0% or more and 5% or less, and as a result, a transparent molded product having a haze of 5% or less can be obtained.

  On the other hand, in the present invention, when the melting point of the B layer of the sheet is higher than the melting point of the A layer of the sheet, the sheet is preheated when the sheet temperature becomes “Tc-30 of the B layer of the sheet” in the preheating step. The average rate of temperature rise until the end is preferably 20 ° C./second or more. The average heating rate here is the time when preheating is completed from when the sheet temperature becomes “Tc-30 of the B layer of the sheet” ° C. when the change in the sheet temperature during preheating is observed with a temperature detector. The temperature difference between the sheet temperature at the end of preheating and the sheet temperature when reaching “Tc-30 of the B layer of the sheet” ° C. The value when divided by the time required to raise the temperature of the region.

  In the preheating step of the method for producing a molded body of the present invention, the mean temperature increasing rate from when the sheet temperature reaches “Tc-30 of the B layer of the sheet” ° C. until the end of preheating is 20 ° C./second or more. Details are described below.

  When the melting point of the B layer of the sheet is higher than the melting point of the A layer of the sheet, if the polyester that is the main component of the B layer is crystallized at the stage of the sheet that is the material of the molded body, It is not easy to melt the polyester which is the main component of the layer. Therefore, in the sheet used for obtaining the molded body, it is assumed that the B layer needs to be in a substantially amorphous state with a relative crystallinity of 0% or more and 5% or less in advance. However, in general, an amorphous polyester has a temperature region in which cold crystallization occurs between the glass transition temperature and the melting point and is lower than the melting point of PBT (melting point: about 225 ° C.). When a polyester such as PET (cold crystallization temperature: about 140 ° C.) having a cold crystallization temperature is used as the main component of the B layer, crystallization proceeds when simply preheating is obtained. The relative crystallinity of the B layer in the molded body is greater than 5%, and the transparency is low. In response to such a problem, the present invention sets the average temperature rising rate from the time when the sheet temperature reaches “Tc-30 of the B layer of the sheet” ° C. to the end of the preheating to 20 ° C./second or more. By making the average heating rate relatively higher than the cold crystallization rate of the layer, crystallization until the end of preheating is suppressed, and the relative crystallinity of the B layer of the molded product is 0% or more and within 5%. In addition, the present inventors have found that it is possible to impart transparency to the molded body. The average heating rate is more preferably 25 ° C./second or more, and further preferably 30 ° C./second or more. The higher the average temperature increase rate, the better. However, considering the mechanical performance, 200 ° C./second is considered the upper limit.

  The sheet used as the material of the molded body of the present invention may contain an additive as long as the object of the present invention is not impaired. Additives (glass fiber, carbon fiber, metal fiber, natural fiber, organic fiber, glass flake, glass bead, ceramic fiber, ceramic bead, asbestos, wollastonite, talc, clay, mica, sericite, zeolite , Bentonite, montmorillonite, synthetic mica, dolomite, kaolin, fine powder silicic acid, feldspar powder, potassium titanate, shirasu balloon, calcium carbonate, magnesium carbonate, barium sulfate, calcium oxide, aluminum oxide, titanium oxide, aluminum silicate, silicon oxide , Gypsum, novaculite, dosonite or clay), UV absorbers (resorcinol, salicylate, benzotriazole, benzophenone, etc.), heat stabilizers (hindered phenol, hydroquinone, phosphite) And substitutes thereof), lubricants, release agents (such as montanic acid and salts thereof, esters thereof, half esters thereof, stearyl alcohol, stearamide and polyethylene wax), dyes (such as nigrosine) and pigments (such as cadmium sulfide and phthalocyanine) ) -Containing colorants, anti-coloring agents (phosphites, hypophosphites, etc.), flame retardants (red phosphorus, phosphate esters, brominated polystyrene, brominated polyphenylene ether, brominated polycarbonate, magnesium hydroxide, melamine And cyanuric acid or salts thereof, silicon compounds, etc.), conductive agents or colorants (carbon black, etc.), slidability improvers (graphite, fluororesins, etc.), antistatic agents, impact resistance agents, etc. 1 type (s) or 2 or more types can be contained.

  Moreover, the sheet | seat which is the material of the molded object of this invention can add 1 type (s) or 2 or more types of crystal nucleating agents in the range which does not impair the objective of this invention as needed. Examples of the crystal nucleating agent include inorganic nucleating agents such as talc, organic nucleating agents such as dibenzylidene sorbitol, sodium benzoate, and sodium montanate.

  In order to impart design properties to the molded body of the present invention, a printing layer can be formed on the surface layer of the sheet that is the material of the molded body, depending on the purpose. The print layer is formed by printing a desired print pattern made up of characters, figures, symbols, patterns, etc. The viewpoint of improving the adhesion between the ink used for the printing layer and the surface layer of the molded body of the present invention or the surface layer of the sheet which is the material of the molded body of the present invention (hereinafter collectively referred to as the surface layer). Therefore, the surface layer may be subjected to pretreatment such as corona treatment, plasma treatment, ozone treatment, flame treatment or the like in an atmosphere of air, nitrogen, or carbon dioxide gas. The printing can be formed by various known printing methods such as gravure printing, offset printing, letterpress printing, screen printing, transfer printing, flexographic printing, and ink jet printing. The ink used for printing may be either water-based ink or non-water-based ink such as solvent-based ink.

  Although there is no restriction | limiting in particular in the thickness of a printing layer, it is preferable that it is 0.1 micrometer-10 micrometers from a viewpoint of printing appearance, More preferably, they are 0.2 micrometer-3 micrometers, More preferably, they are 0.4 micrometer-1 micrometer.

  Below, the manufacturing method of the molded object of this invention is described.

  Each extruder is melt-extruded with the resin composition that is the raw material of the A layer on one side and the B layer on the other side. After removing foreign matter with a wire mesh and optimizing the flow rate with a gear pump, Supply to the installed feed block. The multi-manifold base or the feed block is provided with a desired number of channels having a desired shape in accordance with the required layer structure of the film. The molten resin extruded from each extruder is merged by the multi-manifold die or the feed block as described above, and coextruded into a sheet form from the die. The sheet is brought into close contact with a casting drum by an air knife or a method such as electrostatic application, and is cooled and solidified to form a non-oriented sheet having a haze of 5% or less.

  Here, it is preferable to use a wire mesh mesh of 50 to 400 mesh in order to prevent surface roughness due to mixing of foreign matters such as gels and thermally deteriorated materials.

  In order to make the non-oriented sheet obtained as described above into a molded product, the temperature at the end of preheating in the indirect heating method is “melting point of sheet A layer −20” ° C. or more “melting point of sheet A layer + 20” ° C. Molding is performed as follows.

  The lower limit of the mold temperature in the molding step is preferably equal to or higher than the glass transition temperature of the A layer of the sheet from the viewpoint of relaxing and removing the strain generated by the molding. On the other hand, considering the mold releasability and the cooling cycle of the molded body, the upper limit is preferably 120 ° C. The mold temperature in the molding step is more preferably “glass transition temperature of sheet A layer + 5” ° C. or more and 100 ° C. or less, more preferably “glass transition temperature of sheet A layer + 10” ° C. or more and 90 ° C. or less.

[Methods for measuring physical properties and methods for evaluating effects]
1. An ATR measurement accessory is attached to the GTG fraction Fourier transform infrared spectrometer Spectrum 100 (manufactured by PerkinElmer Co., Ltd.) of the A layer of the molded body, and the spectrum of the A layer of the molded body is measured. After performing ATR correction on the obtained spectrum, the transmittance is converted into absorbance. Next, the absorbance spectrum at 891 cm ^{−1 and} the absorbance at 951 cm ⁻¹ are connected by a straight line, and a difference spectrum between the absorption spectrum and the baseline is obtained in the region from 891 cm ⁻¹ to 951 cm ⁻¹ . Using the absorbance at ₉₃₄ cm ⁻¹ (hereinafter referred to as “A _934” ) and the absorbance at ₉₁₆ cm ⁻¹ (hereinafter referred to as “A _916” ) in the obtained difference spectrum, the GTG fraction is obtained by Equation 1.

GTG fraction = A ₉₁₆ / (A ₉₃₄ + A ₉₁₆ ) (Equation 1)
The measurement conditions are as follows.

Number of integration: 8 times Wavelength interval: 1 cm ⁻¹ .

2. Melting point, cold crystallization temperature (Tc), glass transition temperature (Tg), ΔTcg of each layer of sheet and molded body
A layer or B layer is scraped off from a sheet or a molded product to collect a sample of 5 mg, and a temperature increase rate from 20 ° C. to 300 ° C. using a differential scanning calorimeter DSCII type (manufactured by Seiko Instrument Co., Ltd.) The temperature is raised for 5 minutes, held for 5 minutes, rapidly cooled to 20 ° C. at 999 ° C./minute, held for 5 minutes, and then heated again at 20 ° C./minute.

  In the measurement of the B layer, the peak top temperature of the exothermic peak accompanying crystallization observed at this time is defined as the cold crystallization temperature (Tc) of the B layer. In the measurement of the B layer, the peak top temperature of the endothermic peak accompanying melting observed at this time is defined as the melting point of the B layer. Further, for the A layer, the peak top temperature of the endothermic peak accompanying melting observed at the time of measurement is also defined as the melting point of the A layer.

  Next, a method for measuring ΔTcg in the B layer of the molded body will be described below. Similarly to the measurement of the melting point and Tc, the glass transition temperature (Tg) of the B layer is read from the change in the baseline curve observed during the second temperature increase.

  From the Tc and Tg of the B layer of the molded body obtained by these measurements, ΔTcg of the B layer of the molded body is obtained by Equation 2.

ΔTcg = Tc−Tg (Equation 2)
Also, regarding the Tg of the A layer in the sheet, the value obtained in the second temperature rise measurement is set as the Tg of the A layer as in the B layer.

  In the DSC measurement of the B layer of the molded product, when two or more melting points exist, the highest value among the observed melting points is set as the melting point of the B layer of the molded product. Similarly, in the DSC measurement of the B layer of the molded body, when two or more Tg are present, the highest Tg observed is set as the Tg of the B layer of the molded body. In the DSC measurement of the B layer of the molded body, when two or more Tc are present, the lowest Tc value among the observed Tc is set as the Tc of the B layer of the molded body. The same applies to the melting point, (Tc), and glass transition temperature (Tg) of the B layer of the sheet.

  In the DSC measurement of the A layer of the molded product, when two or more melting points exist, the highest value among the observed melting points is set as the melting point of the A layer of the molded product. The same applies to the melting point of the A layer of the sheet. As for the glass transition temperature (Tg) of the A layer of the sheet, similarly to the glass transition temperature (Tg) of the B layer of the sheet, when there are two or more Tg, the highest Tg observed. Is the Tg of the A layer of the sheet.

3. Relative crystallinity of the B layer From the sheet or molded body as the material of the molded body, only the B layer is scraped and a sample of 5 mg is collected, and a differential scanning calorimetry DSCII type (manufactured by Seiko Instrument Co., Ltd.) is used. The temperature is raised from deg. C to 300 deg. The relative crystallinity was calculated according to Equation 3 using the melting peak area (Sm) and the exothermic peak area (Sc) observed by DSC measurement.

  Relative crystallinity = (Sm−Sc) / Sm × 100 (Equation 3)

4). Transparency: Haze value (%)
Using a haze meter HGM-2DP type (manufactured by Suga Test Instruments Co., Ltd.), the haze value of the molded body and the sheet serving as the material thereof is measured. In the case of a molded body, measurement is performed by cutting a sample from a portion having flatness in order to eliminate light scattering and transmission distance non-uniformity resulting from bending of the sample. The measurement is performed 5 times per sample, and the average value (average haze value) of the 5 measurements is obtained. Subsequently, a value converted to 250 μm was obtained by Equation 4.

Haze value = average haze value × 250 (μm) / sample thickness (μm) (Formula 4)
The sample thickness is 10 points arbitrarily selected using a dial gauge thickness gauge (JIS B7503: 1997, UPAIGHT DIAL GAUGE (0.001 × 2 mm), No. 25, measuring element 5 mmφ flat type manufactured by PEACOCK). The average value is measured as the sample thickness (μm) of the sample.

5. Plane orientation coefficient (fn)
Using the Abbe refractometer with sodium D-line (wavelength 589 nm) as the light source, the longitudinal refractive index (Nx), the lateral refractive index (Ny) and the refractive index (Nz) in the thickness direction of the sheet surface are measured. From the above, the plane orientation coefficient (fn) is calculated.

  fn = (Nx + Ny) / 2−Nz (Expression 5)

6). Sheet temperature in the preheating step In the indirect heating method, the temperature is measured by an infrared radiation thermometer installed at a distance of 30 cm from the sheet.

7). Heat Resistance of Molded Body The lid-shaped molded body is placed in a hot air oven at 90 ° C. for 2 minutes with the bottom of the molded body facing up, and is taken out of the oven after the test and naturally cooled. After completion of cooling, using the initial height before charging the hot air oven and the height after testing after charging the hot air oven, the height maintenance factor is calculated according to Equation 6 to evaluate the heat resistance.

Height maintenance factor = (initial height−height after test) / initial height × 100 (Equation 6)
When the height maintenance rate obtained by Equation 6 is 70% or more, it is determined that the heat resistance at a practical level is satisfied.

8. 100 ° C heat shrinkage (%)
A sample piece for measurement is cut out from the molded body into a size of 150 mm × 10 mm. In addition, in the below-mentioned Example, although cut out from the bottom part of a molded object, you may cut out this sample from any site | part of a molded object. This sample piece is left in an atmosphere of 23 ° C. and a relative humidity of 60% for 30 minutes, and in that atmosphere, two marks are made at intervals of about 100 mm in the longitudinal direction of the sample, and a Nikon universal projector (Model V- 16A), the interval between the marks is measured, and the value is A. Next, the sample is hung in a gear oven under a load of 3 g and left in an atmosphere at 100 ° C. for 30 minutes. Next, after cooling and conditioning in an atmosphere of 23 ° C. and a relative humidity of 60% for 1 hour, the interval between the first marks is measured. At this time, the thermal contraction rate was calculated from the following formula (i). The number of tests is 3, and the average value is adopted.

      Thermal contraction rate (%) = 100 × (A−B) / A (i)

9. -20 ° C Charpy impact strength (MJ / m ² )
From the molded body, a sample piece for measurement is cut into a size of 50 mm × 10 mm. The sample piece is cooled to −20 ° C. with a refrigerator. Sample taken from refrigerator in Charpy impact tester (capacity: 10 kg · cm, hammer weight: 1.019 kg, hammer lift angle: 127 degrees, distance from axis to center of gravity: 6.12 cm) manufactured by Toyo Seiki Seisakusho Is measured in an atmosphere of 23 ° C. and 60% relative humidity with the long (50 mm) side of the sample fixed. The number of tests is 10, and the average value is adopted. The average value is divided by the cross-sectional area of the sample (sample thickness × 10 mm) and converted to a unit of MJ / m ² .

10. Stacked thickness of molded body and sheet Using Leica DMLM manufactured by Leica Microsystems Co., Ltd., photographed the transmitted light of the cross section of the film at a magnification of 100 times, and measured the layer thickness of each layer of the molded body and the sheet. .

  Although it shows concretely by an Example, this invention is not a thing limited to these Examples.

  The raw materials used in the production examples, examples, and comparative examples of the molded body of the present invention are as follows. In the examples and comparative examples, the following abbreviations may be used.

PBT-A: polybutylene terephthalate (melting point 225 ° C.)
PBT-B: polybutylene (terephthalate / isophthalate) (melting point 205 ° C. terephthalic acid: isophthalic acid = 90 mol%: 10 mol%)
PBT-C: polybutylene (terephthalate / isophthalate) (melting point 170 ° C. terephthalic acid: isophthalic acid = 70 mol%: 30 mol%)
PET-A: Polyethylene terephthalate (melting point 250 ° C.)
PET-B: Polyethylene terephthalate (melting point 250 ° C.)
PET-C: polyethylene terephthalate / isophthalate) (melting point 205 ° C. terephthalic acid: isophthalic acid = 82.5 mol%: 17.5 mol%)
PLA-A: crystalline poly-L-lactic acid (“Ingeo” 4032D manufactured by Nature Works; D-form amount = 1.4 mol%, melting point = 168 ° C., Tg = 58 ° C.)
The measurement methods used in Examples and Comparative Examples are as described in [Methods for measuring physical properties and methods for evaluating effects] above.

Example 1
Into the vent type extruder (1), 100% by mass of PBT-A that had been previously vacuum-dried as the raw material for the A layer was charged, melted and kneaded at 250 ° C. while degassing the vacuum vent part, and extruded to 100 mesh. The polymer was filtered through a metal mesh mesh and supplied to a multi-manifold base of two types and three layers. In addition, 100% by mass of PET-A that has been previously vacuum-dried as a raw material for the B layer is introduced into the vent-type extruder (2), and melt-kneaded at 280 ° C. and extruded while degassing the vacuum vent part. The polymer was filtered through a mesh mesh of 100 mesh in a flow path different from that of the extruder (1), and then co-extruded into a sheet form from a T die die set at a die temperature of 270 ° C. An electrostatic application method and an air chamber method were used in combination at both ends using a needle-like edge pinning device and electrostatically adhered to a casting drum cooled to 20 ° C. to cool and solidify to obtain an unstretched sheet.

  The obtained sheet | seat was 250 micrometers and the thickness structure was A layer / B layer / A layer = 1/8/1.

Subsequently, using the obtained sheet as a material, indirect heating type vacuum / pressure forming was performed with an FKS vacuum / pressure forming machine manufactured by Asano Laboratory. In molding, a lid-shaped mold having an opening of 132 mm × 183 mm, a bottom of 112 mm × 160 mm, and a depth of 25 mm is used, and molding is performed under the conditions of a heater temperature of 600 ° C., a pneumatic pressure of 3 kg / cm ² , and a mold temperature of 60 ° C. went. The result of the obtained molded body was as shown in Table 1, and had transparency and heat resistance. Moreover, the thermal shrinkage rate at 100 ° C. was small, and the Charpy impact strength at −20 ° C. showed a large value.

(Examples 2-17, Comparative Examples 1-7)
Examples 2 to 17 and Comparative Examples 1 to 7 are as shown in Table 1 or Table 2 as raw materials used for the resin of the A layer and the B layer, the extruder (1), and the extruder (2), and the molding conditions. A sheet and a molded body were obtained in the same manner as in Example 1 except that was changed as shown in Table 1. The physical properties of the obtained sheet and molded product are shown in Table 1 or Table 2.

(Example 18)
The sheet obtained in Example 1 was finely cut to prepare 30% of a flaky raw material. A sheet and a molded body were obtained in the same manner as in Example 1 except that this raw material and 70% of the PET-A raw material were used as the B layer raw material. The physical properties of the obtained sheet and molded product are shown in Table 1.

Claims (7)

A molded body obtained from a sheet,
The molded body has a layer (hereinafter referred to as “A layer”) containing polybutylene terephthalate (hereinafter referred to as “PBT”) as a main component, and a layer (hereinafter referred to as “B layer”) whose main component is a polyester other than PBT. ,
In the molded body, the A layer is located on at least one surface,
A molded article satisfying the following (1) and (2).
(1) The GTG fraction of the A layer of the molded body is 0.6 or more and 1 or less.
(2) The relative crystallinity of the B layer of the molded body is 0% or more and 5% or less. The melting point of the B layer of the molded body is higher than the melting point of the A layer of the molded body,
The molded body according to claim 1, wherein the B layer of the molded body has a difference (ΔTcg) between the cold crystallization temperature (Tc) and the glass transition temperature (Tg) of 35 ° C or higher.   The molded body according to claim 1 or 2, wherein the B layer of the molded body comprises a layer mainly composed of polyethylene terephthalate (hereinafter referred to as PET). The molded body according to any one of claims 1 to 3, wherein the molded body satisfies the following (1) and / or (2).
(1) The heat shrinkage rate of the molded body at 100 ° C. is 0% or more and 7% or less.
(2) The Charpy impact strength at −20 ° C. of the molded body is 0.4 MJ / m ² or more.   The molding according to any one of claims 1 to 4, wherein the lamination ratio "total thickness of layer A" / "total thickness of layer B" of the molded product is a ratio of 1/15 to 1/2. body. A method for producing a molded body having a step of preheating a sheet (hereinafter referred to as a preheating step) and a step of forming a sheet (hereinafter referred to as a molding step) in this order,
The sheet has an A layer and a B layer, and in the sheet, the A layer is located on at least one surface,
The sheet | seat temperature at the time of completion | finish of the preheating in a preheating process is "the melting | fusing point of the A layer of a sheet -20" degree C or more and "the melting point of the A layer of a sheet +20" degree C or less. Manufacturing method.   The melting point of the B layer of the sheet is higher than the melting point of the A layer, and in the preheating step, the average temperature rise from when the sheet temperature reaches “Tc-30 of the B layer of the sheet” ° C. until the end of preheating. The manufacturing method of the molded object of Claim 6 whose speed is 20 degrees C / sec or more.