WO2018199091A1 - 積層複合体およびその製造方法 - Google Patents
積層複合体およびその製造方法 Download PDFInfo
- Publication number
- WO2018199091A1 WO2018199091A1 PCT/JP2018/016612 JP2018016612W WO2018199091A1 WO 2018199091 A1 WO2018199091 A1 WO 2018199091A1 JP 2018016612 W JP2018016612 W JP 2018016612W WO 2018199091 A1 WO2018199091 A1 WO 2018199091A1
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- WO
- WIPO (PCT)
- Prior art keywords
- laminated composite
- resin
- core layer
- porosity
- reinforcing fibers
- Prior art date
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Images
Classifications
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- B32B5/22—Layered products characterised by the non- homogeneity or physical structure, i.e. comprising a fibrous, filamentary, particulate or foam layer; Layered products characterised by having a layer differing constitutionally or physically in different parts characterised by the presence of two or more layers which are next to each other and are fibrous, filamentary, formed of particles or foamed
- B32B5/24—Layered products characterised by the non- homogeneity or physical structure, i.e. comprising a fibrous, filamentary, particulate or foam layer; Layered products characterised by having a layer differing constitutionally or physically in different parts characterised by the presence of two or more layers which are next to each other and are fibrous, filamentary, formed of particles or foamed one layer being a fibrous or filamentary layer
- B32B5/26—Layered products characterised by the non- homogeneity or physical structure, i.e. comprising a fibrous, filamentary, particulate or foam layer; Layered products characterised by having a layer differing constitutionally or physically in different parts characterised by the presence of two or more layers which are next to each other and are fibrous, filamentary, formed of particles or foamed one layer being a fibrous or filamentary layer another layer next to it also being fibrous or filamentary
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- B32B27/08—Layered products comprising a layer of synthetic resin as the main or only constituent of a layer, which is next to another layer of the same or of a different material of synthetic resin
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- D04H1/00—Non-woven fabrics formed wholly or mainly of staple fibres or like relatively short fibres
- D04H1/40—Non-woven fabrics formed wholly or mainly of staple fibres or like relatively short fibres from fleeces or layers composed of fibres without existing or potential cohesive properties
- D04H1/54—Non-woven fabrics formed wholly or mainly of staple fibres or like relatively short fibres from fleeces or layers composed of fibres without existing or potential cohesive properties by welding together the fibres, e.g. by partially melting or dissolving
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Definitions
- the present invention relates to a laminated composite and a method for producing the same.
- weight reduction of the members constituting the aircraft is strongly desired from the viewpoint of improving fuel consumption and environmental protection.
- a sandwich material in which a honeycomb layer and a foam material are disposed in the core layer and a carbon fiber reinforced plastic is disposed in the skin layer is used.
- the manufacture of the interior member requires a process of bonding the core layer and the skin layer, and thus there is a problem that the manufacturing process becomes complicated and the productivity is lowered.
- Patent Document 1 Japanese Patent Publication No. 2014-503694 proposes a porous article manufacturing composition including a plurality of reinforcing fibers, polyimide fibers, and polymer binder fibers.
- a polyimide fiber is used to obtain a base material having flame retardancy and low smoke generation, and by heating the base material, the polyimide fiber, which is a thermoplastic resin, is softened. It has been shown that a base material that is lightweight and has excellent formability can be obtained because the bending is eliminated and the film expands.
- stacking of the skin layer is not essential, there existed a subject that intensity
- Patent Document 2 Japanese Patent Publication No. 2007-530320
- a composite sheet material has been proposed. According to Patent Document 2, it is shown that flame retardancy and low smoke generation are improved by the skin layer.
- a scrim, a film, etc. were used for the skin layer, there existed a problem that the integrity of the whole composite sheet-like material was inferior, and intensity
- an object of the present invention is to solve the above-mentioned problems, and to provide a laminated composite having flame retardancy and low smoke generation, excellent in unity and high mechanical properties.
- Another object of the present invention is to provide a laminated composite which can be easily adjusted in shape and density by heat expansion molding and has excellent formability.
- the core layer is a composite in which at least intersections of randomly dispersed non-continuous reinforcing fibers are bonded with a first thermoplastic resin.
- the skin layer is a composite in which continuous reinforcing fibers are impregnated with a second thermoplastic resin.
- the limiting oxygen index of the first and second thermoplastic resins is 30 or more (preferably 32 or more, more preferably 35 or more).
- the first and second thermoplastic resins are compatible with each other.
- the first and second thermoplastic resins are a polyetherimide resin, a polyetheretherketone resin, a polyetherketoneketone resin, a polyethersulfone resin, a thermoplastic polyimide resin, and a flame retardant addition, respectively.
- the laminated composite according to Aspect 1 or Aspect 2 which is at least one resin selected from the group consisting of a polycarbonate-based resin and a flame retardant-added polyester-based resin.
- Aspect 4 The laminated composite according to any one of aspects 1 to 3, wherein the first and second thermoplastic resins are the same.
- the core layer material is composed of non-continuous reinforcing fibers and fibrous and / or particulate first thermoplastic resin, and these are randomly dispersed nonwoven fabrics
- the skin layer material is composed of a fabric made of continuous reinforcing fibers and a second thermoplastic resin for impregnating the fabric,
- the present invention by combining the core layer and the skin layer, it is possible to obtain a laminated composite having excellent flame retardancy and low smoke generation performance as well as excellent mechanical properties. Furthermore, in a preferred embodiment, a laminated composite that can be easily adjusted in shape and density by heat expansion molding and has excellent formability can be obtained.
- FIG. 2 is a scanning electron microscope (SEM) photograph of the core layer in the laminated composite produced in Example 1.
- FIG. 2 is a scanning electron microscope (SEM) enlarged photograph of the core layer in the laminated composite produced in Example 1.
- SEM scanning electron microscope
- the laminated composite of the present invention has a laminated structure including at least one core layer and at least one skin layer, and is important to be a laminated composite satisfying all the following conditions (A) to (D) It is.
- the core layer is a composite in which at least intersections of randomly dispersed non-continuous reinforcing fibers are bonded with a first thermoplastic resin.
- the skin layer is a composite in which continuous reinforcing fibers are impregnated with a second thermoplastic resin.
- the limiting oxygen index (LOI) of the first and second thermoplastic resins is 30 or more.
- the first and second thermoplastic resins are compatible with each other.
- the core layer is a composite in which at least intersections of randomly dispersed non-continuous reinforcing fibers are bonded with the first thermoplastic resin, for example, a structure in which the non-continuous reinforcing fibers are randomly intersected, It is formed of a composite having an open cell structure that is partially or entirely bonded.
- a non-woven fabric containing discontinuous reinforcing fibers and a fibrous and / or particulate first thermoplastic resin may be used as the core layer material.
- Non-continuous reinforcing fibers used for the core layer are metal fibers such as aluminum fibers, brass fibers and stainless fibers, glass fibers, polyacrylonitrile-based, rayon-based, lignin-based, pitch-based carbon fibers and graphite fibers, silicon carbide fibers, Examples thereof include inorganic fibers such as silicon nitride fiber, alumina fiber, silicon carbide fiber, and boron fiber, and these are used alone or in combination of two or more. Among these, it is preferable to use carbon fiber from the point which can give a low specific gravity and a high bending elastic modulus with respect to the laminated composite obtained.
- the fiber length of the discontinuous reinforcing fibers is preferably 5 to 100 mm, more preferably 7 to 70 mm, and still more preferably 10 to 50 mm, from the viewpoint of enhancing the expandability in the laminated composite. If the fiber length is too short, in the expansion of the laminated composite due to the release of the bending imparted to the discontinuous reinforcing fibers of the core layer, the degree of expansion may be reduced and the density of the core layer may be decreased. It may not be possible. On the other hand, if the fiber length is too long, for example, in the process of producing a nonwoven fabric by a wet raid process, fiber twist or poor dispersion may occur, which may deteriorate process passability.
- the first thermoplastic resin used for the core layer has a limiting oxygen index (LOI) of 30 or more. Preferably it is 32 or more, More preferably, it is 35 or more. If a thermoplastic resin having an LOI that is too small is used, the flame retardancy of the laminated composite may be reduced.
- LOI limiting oxygen index
- the first thermoplastic resin used in the core layer of the present invention include fluorine resins such as polytetrafluoroethylene resins; heats such as semi-aromatic polyimide resins, polyamideimide resins, and polyetherimide resins.
- Plastic polyimide resins Polysulfone resins such as polysulfone resins and polyethersulfone resins; Semi-aromatic polyamide resins; Polyethers such as polyether ketone resins, polyether ether ketone resins and polyether ketone ketone resins Examples thereof include ketone resins; polycarbonate resins; polyarylate resins; liquid crystal polyester resins such as wholly aromatic polyester resins.
- the LOI of the resin may satisfy a predetermined range by adding a flame retardant, and examples of such a resin include general-purpose resins (for example, polyester resins) to which a flame retardant is added.
- the flame retardant examples include halogen compounds (chlorine compounds, bromine compounds, specifically, chlorinated paraffin, chlorinated paraffin, chlorinated polyethylene, tetrabromoethane, tetrabromobisphenol A, etc.), phosphate esters ( For example, tricresyl phosphate, cresyl diphenyl phosphate, triphenyl phosphate, trioctyl phosphate, etc., halogen-containing phosphate ester (for example, tris (chloroethyl) phosphate, bis (2,3-dibromopropyl) -2,3 dichloro) Propyl phosphate) and inorganic compounds (antimony trioxide, aluminum hydroxide, borate, etc.). These flame retardants may be used alone or in combination of two or more.
- halogen compounds chlorine compounds, bromine compounds, specifically, chlorinated paraffin, chlorinated paraffin, chlorinated polyethylene, tetrabromo
- polyetherimide resin polyetheretherketone resin, polyetherketoneketone resin, polyethersulfone resin, polycarbonate resin (preferably polycarbonate resin with flame retardant added), flame retardant added
- polycarbonate resin preferably polycarbonate resin with flame retardant added
- flame retardant added The polyester-type resin etc. which were used are used suitably, and what mixed these individually or in mixture of 2 or more types can be used.
- the particles of the first thermoplastic resin preferably have a particle size of 1.5 mm or less, and more preferably have a particle size of 1.0 mm or less. Although the minimum of a particle size is not specifically limited, For example, about 0.01 mm may be sufficient.
- the average fineness of the thermoplastic fiber is preferably 0.1 to 10 dtex, more preferably 0.2 to 9 dtex, more preferably 0.3 to 8 dtex.
- the average fineness is too small, the constituent fibers are entangled in the process of producing the nonwoven fabric.
- the average fiber length of the thermoplastic fiber is preferably 0.5 to 60 mm. If the average fiber length is too short, the fibers may fall off in the process of producing the nonwoven fabric, and in particular when producing the nonwoven fabric by the wet raid process, the drainage in the process becomes worse and the process passability is reduced. There is a risk of greatly deteriorating. On the other hand, if the average fiber length is too long, the constituent fibers tend to be entangled in the step of producing the nonwoven fabric, and the reinforcing fibers may not be uniformly dispersed.
- the thickness is preferably 1 to 55 mm, more preferably 3 to 50 mm.
- the method for producing the thermoplastic fiber is not particularly limited as long as the fiber shape can be obtained, and a known melt spinning apparatus can be used. That is, it is obtained by melting and kneading thermoplastic resin pellets and powders with a melt extruder, introducing the melted resin into a spinning cylinder, measuring it with a gear pump, and then winding the yarn discharged from the spinning nozzle.
- the take-up speed at that time is not particularly limited, but it is preferably taken in the range of 500 to 4000 m / min from the viewpoint of reducing the occurrence of molecular orientation on the spinning line.
- the core layer may be the first thermoplastic resin (that is, a thermoplastic resin having a limiting oxygen index (LOI) of 30 or more as needed) within a range not impairing the flame retardancy and low smoke generation of the laminated composite. Resins other than) may be included.
- the core layer material may include discontinuous reinforcing fibers, a fibrous first thermoplastic resin, and a polymer binder for bonding these fibers.
- the polymer binder may be in the form of particles, fibers, liquids, etc., but binder fibers are preferred from the viewpoint of forming a nonwoven fabric.
- the polymer binder is not particularly limited, and examples thereof include polyolefin resins, polyamide resins, polyester resins, acrylic resins, polyvinyl alcohol resins, polyurethane resins, and the like, and polyester resins are preferable.
- a molar ratio 100/0 to 40/60. (Preferably 99/1 to 40/60).
- the polyester-based resin may contain a small amount of other dicarboxylic acid components other than terephthalic acid and isophthalic acid in combination of one kind or a plurality of kinds as long as the effects of the present invention are not impaired.
- a diol component which comprises a polyester-type resin although ethylene glycol can be used as a diol component, you may contain a small amount of other diol components other than ethylene glycol combining 1 type or multiple types.
- the production method of the polyester resin constituting the polyester binder is not particularly limited, and a known method can be applied. That is, it can be produced by a method of melt polymerization through a transesterification reaction using a dicarboxylic acid component and a diol component as starting materials, or a method of melt polymerization after directly esterifying the dicarboxylic component and the diol component.
- polyester binder fibers are particularly preferable.
- the polyester binder fiber may have a crystallinity of, for example, 50% or less, preferably 45% or less, and more preferably 40% or less, from the viewpoint of exhibiting good binder performance.
- the crystallinity can be set to a desired value by adjusting the copolymerization ratio of the dicarboxylic acid component, the stretching ratio in the fiberizing step, and the like. From the viewpoint of molding the laminated composite, the degree of crystallinity of the polyester-based binder fiber may be 5% or more.
- the single fiber fineness of the polyester binder fiber is not particularly limited.
- fibers having an average fineness of 0.1 to 50 dtex, preferably 0.5 to 20 dtex can be widely used.
- the average fiber length of single fibers of the polyester-based binder fiber can be appropriately set according to the required strength of the laminated composite, and may be, for example, 1 to 40 mm, preferably 5 to 35 mm, more preferably May be 10-30 mm.
- the weight of the polymer binder represents the weight of the solid content.
- the nonwoven fabric used as core layer material manufactures by the well-known nonwoven fabric manufacturing process using the said discontinuous reinforcement fiber and the said 1st thermoplastic resin of a fibrous form and / or a particle form at least. can do.
- a wet laid process an air laid process, a dry mixing process, a carding and needle process, and other known processes used to produce nonwoven products, and combinations thereof.
- the first thermoplastic resin of the nonwoven fabric is heated and softened by a heating device, and then the nonwoven fabric is compressed and cooled by a cooling device, whereby the discontinuous reinforcing fibers are bent.
- the core layer having an open cell structure fixed by the first thermoplastic resin can be formed while being applied.
- a heating device for example, a hot air heater, an infrared heater, a hot press, a belt press, and other known processes used for heating resin products, and combinations thereof are used.
- a cooling compression apparatus for example, a nip roller, a calendar roller, a cooling press, a belt press, and other known processes used for heating resin products, and combinations thereof are used.
- the ratio of the discontinuous reinforcing fibers constituting the core layer of the present invention is preferably 20 to 90% by weight, more preferably 30 to 85% by weight, and further preferably 40 to 80% based on the weight of the entire core layer. % By weight. If the ratio of the non-continuous reinforcing fibers is too small, the ratio of the non-continuous reinforcing fibers to the entire core layer is small. Since the ratio of the discontinuous reinforcing fibers in the layer becomes small, the bending elastic modulus as the entire core layer may be lowered.
- the ratio of the discontinuous reinforcing fibers is too large, in the resulting laminated composite, the number of intersections with the reinforcing fibers by the first thermoplastic resin is reduced, and the support of the intersections in the open cell structure becomes insufficient. In addition, the mechanical properties of the laminated composite may be deteriorated.
- the skin layer is a composite in which continuous reinforcing fibers are impregnated with the second thermoplastic resin.
- the continuous reinforcing fiber for example, a woven fabric, a non-crimp fabric (NCF), a one-way alignment material (UD material), a knitted fabric, or the like is preferably used.
- These continuous reinforcing fibers may be used alone or in combination of two or more.
- the skin layer may be in the form of a fabric in which continuous reinforcing fibers are arranged in at least one direction. For example, one skin in which continuous reinforcing fibers are arranged in one direction of warp or weft.
- NCF non-crimp fabric
- the continuous reinforcing fibers include metal fibers such as aluminum fibers, brass fibers and stainless fibers, glass fibers, polyacrylonitrile-based, rayon-based, lignin-based, pitch-based carbon fibers and graphite fibers, silicon carbide fibers, silicon nitride fibers, Examples thereof include inorganic fibers such as alumina fibers, silicon carbide fibers, and boron fibers, and these are used alone or in combination of two or more. Among these, it is preferable to use carbon fiber from the viewpoint of imparting a high elastic modulus and low specific gravity to the laminated composite.
- the second thermoplastic resin used for the skin layer needs to have a limiting oxygen index (LOI) of 30 or more. Preferably it is 32 or more, More preferably, it is 35 or more. When the second thermoplastic resin having an LOI that is too small is used, the flame retardancy of the laminated composite is lowered, which is not preferable.
- LOI limiting oxygen index
- examples of the second thermoplastic resin used in the skin layer of the present invention include fluorine resins such as polytetrafluoroethylene resins; polyimides such as semi-aromatic polyimide resins, polyamideimide resins, and polyetherimide resins.
- Polysulfone resins such as polysulfone resins and polyethersulfone resins; Semi-aromatic polyamide resins; Polyether ketone resins such as polyether ketone resins, polyether ether ketone resins and polyether ketone ketone resins Resin; Polycarbonate resin; Polyarylate resin; Liquid crystal polyester resin such as wholly aromatic polyester resin.
- the LOI of the resin may satisfy a predetermined range by adding a flame retardant, and examples of such a resin include general-purpose resins (for example, polyester resins) to which a flame retardant is added.
- polyetherimide resin polyetheretherketone resin, polyetherketoneketone resin, polyethersulfone resin, polycarbonate resin (preferably polycarbonate resin with flame retardant added), flame retardant added
- polycarbonate resin preferably polycarbonate resin with flame retardant added
- flame retardant added flame retardant added
- the polyester-type resin etc. which were used are used suitably, and what mixed these individually or in mixture of 2 or more types can be used.
- the form of the second thermoplastic resin is not particularly limited, and various forms such as a film form, a powder form, and a non-woven form can be used.
- the skin layer it can be produced by a known composite production process using the continuous reinforcing fiber and the second thermoplastic resin.
- known processes such as hot press, hot melt, resin impregnation with a solvent, and combinations thereof can be used.
- the ratio of the continuous reinforcing fibers constituting the skin layer is 40 to 80% by weight, preferably 45 to 75% by weight, more preferably 50 to 70% by weight, based on the weight of the entire skin layer.
- the ratio of the reinforcing fibers is too small, the amount of resin increases and the elastic modulus may decrease.
- the resin non-impregnation location will arise and there exists a possibility that mechanical characteristics, such as bending strength and a bending elastic modulus, may fall.
- the laminated composite of the present invention has a laminated structure including at least one core layer and at least one skin layer.
- the first and second heats are provided from the viewpoint of enhancing the adhesion between the skin layer and the core layer and imparting light weight and high flexural modulus to the laminated composite. It is important that the plastic resins are compatible with each other.
- compatible refers to a state in which two or more kinds of resins are mixed at the molecular level.
- difference in solubility parameter hereinafter sometimes referred to as SP value
- SP value solubility parameter
- the solubility parameter difference ⁇ (J / cm 3 ) 1/2 is preferably 4 or less, more preferably 3 or less, still more preferably 2 or less, and most preferably 0.
- the solubility parameter used in the present invention is described in Polymer Handbook Fourth Edition Volume 2 (A John Wiley & Sons, Inc., Publication) J. BRANDRUP, EH IMMERGUT, and EA GRULKE (1999) P.675-714. This is the value obtained using the method.
- the first thermoplastic resin and the second thermoplastic resin can be freely combined.
- the first thermoplastic resin and the second thermoplastic resin are the same type of resins.
- combinations of compatible resins include polyetherimide resins and polycarbonate resins (preferably flame retardant-added polycarbonate resins), polyetherimide resins and polyether ether ketone resins, and polyether ether ketone resins. Examples thereof include resins and polyether ketone ketone resins, polyether imide resins and flame retardant-added polyester resins.
- the laminated composite of the present invention is not particularly limited with respect to the laminated structure of the skin layer and the core layer, and various properties can be imparted to the laminated composite by arbitrarily setting the laminated structure of the skin layer and the core layer. Can do.
- a skin layer and a core layer are laminated in the order of “skin-core-skin”, and a skin layer having a high strength and a high elastic modulus is disposed on the outermost layer where the load of bending stress is the strongest.
- a laminated composite having high strength and elastic modulus is obtained.
- the laminated composite of the present invention includes a step of laminating at least one core layer material and at least one skin layer material to form a laminate, and heating and compressing the laminate, followed by cooling. And at least a step of integrating the laminate.
- the core layer material may be a non-woven fabric in which at least the non-continuous reinforcing fibers and the fibrous and / or particulate first thermoplastic resin are randomly dispersed.
- the said skin layer material may be comprised with the fabric which consists of a continuous reinforcement fiber, and the 2nd thermoplastic resin for impregnating the said fabric, 2nd thermoplasticity
- the precursor before impregnation with resin may be sufficient, and the composite_body
- the crystalline resin is heated at a temperature higher than the glass transition temperature of the resin.
- the first and second thermoplastic resins are compatible, and the core layer
- the discontinuous reinforcing fiber can be bent.
- the first and second thermoplastic resins need to be compatible with each other.
- the first and second thermoplastic resins may be the same.
- the discontinuous reinforcing fibers of the core layer are bent.
- such a laminated composite may be used for further expansion.
- the porosity of the laminated composite after the integration step is preferably 0 to 20%, more preferably 0 to 15%, and still more preferably 0 to 10%.
- the porosity of the laminated composite after the integration step is too large, the inside of the laminated composite is not sufficiently heated during heating in the expansion step described later, and the core layer may not be uniformly expanded. In that case, there is a possibility that the formability of the laminated composite due to thermal expansion is deteriorated.
- the laminated composite further includes a step of further heating the laminated composite obtained after the integration step so as to release the bending of the discontinuous reinforcing fibers and expand the laminated composite.
- the manufacturing method of may be included.
- the laminated composite can be formed by an expansion process.
- the present invention provides the laminated composite obtained by heating the laminated composite obtained after the integration step (for example, a laminated composite in which the discontinuous reinforcing fibers of the core layer are bent).
- You may include the manufacturing method of a laminated composite including the process of expanding a body.
- the laminated composite can be formed by an expansion process.
- Examples of the laminated composite obtained after the integration step include the laminated composite described in the aspect 8 described above.
- the thermoplastic resin of the laminated composite is plasticized and the bending of the discontinuous reinforcing fibers of the core layer is released. Therefore, only the core layer can be selectively expanded in the laminated composite. At this time, by heating and solidifying the laminated composite in an arbitrary mold, the laminated composite expands along the target mold. Can be formed.
- the skin layer as the outer layer has high rigidity and the core layer as the inner layer has a low density, so that the laminated composite can have both light weight and high mechanical properties.
- a heating method such as far-infrared rays, hot air, and hot plate contact is used.
- the laminated composite having a porosity of 0 to 20% (preferably 0 to 15%, more preferably 0 to 10%) is heated, It is preferable to expand so that the porosity of the laminated composite after heating is larger than the porosity of the laminated composite before heating (for example, the porosity of the laminated composite is 20 to 80%).
- the porosity of the laminated composite after forming is preferably 20 to 80%, more preferably 25 to 80%, still more preferably 30 to 80%.
- the porosity is too small, there is a possibility that weight reduction of the obtained laminated composite will be insufficient.
- the porosity is too large, the mechanical properties may be insufficient in the laminated composite after forming.
- the porosity of the core layer and the skin layer may be measured separately to grasp the shape of the laminated composite.
- the porosity of the core layer may be higher than the porosity of the skin layer.
- the porosity of the core layer is 2 times or more (for example, 2 to 20 times), preferably 5 times or more, more preferably the skin layer. May be 10 times higher.
- the porosity of the core layer and the skin layer may be obtained by cutting the laminated composite and obtaining a sample of only the core layer and the skin layer, and then obtaining the porosity of each cut portion.
- the weight ratio (core ratio) of the core layer to the entire laminated composite is preferably 20 to 75% by weight, more preferably 22 to 73% by weight, and still more preferably 24 to 70% by weight.
- core ratio is too small, the expansion rate is not sufficient, and problems such as poor formability may occur.
- core ratio is too large, there is a possibility that a problem inferior in mechanical properties such as bending strength and bending elastic modulus may occur.
- the laminated composite contains additives such as an antioxidant, an antistatic agent, a radical inhibitor, a matting agent, an ultraviolet absorber, a flame retardant, and various inorganic substances within a range not impairing the effects of the present invention. May be.
- additives such as an antioxidant, an antistatic agent, a radical inhibitor, a matting agent, an ultraviolet absorber, a flame retardant, and various inorganic substances within a range not impairing the effects of the present invention. May be.
- specific examples of such inorganic substances include carbon materials such as carbon nanotubes, fullerenes, carbon black, graphite, and silicon carbide; talc, wollastonite, zeolite, sericite, mica, kaolin, clay, pyrophyllite, silica, bentonite, and alumina.
- Silicate materials such as silicates; metal oxides such as silicon oxide, magnesium oxide, alumina, zirconium oxide, titanium oxide and iron oxide; carbonates such as calcium carbonate, magnesium carbonate and dolomite; sulfates such as calcium sulfate and barium sulfate Hydroxides such as calcium hydroxide, magnesium hydroxide and aluminum hydroxide; glasses such as glass beads, glass flakes and glass powder; ceramic beads; boron nitride and the like are used.
- the laminated composite after the forming mold preferably satisfies the bending elastic modulus of 10 GPa or more and the specific bending rigidity of 2.5 or more, more preferably 11 GPa. Or more and 2.7 or more, more preferably 12 GPa or more and 3 or more. If the flexural modulus is too small, for example, it may be inferior in mechanical properties as an interior member in an aircraft or a railway vehicle.
- the laminated composite after the forming mold preferably has a bending strength of 100 MPa or more, more preferably 110 MPa, and still more preferably 120 MPa or more.
- a bending strength of 100 MPa or more, more preferably 110 MPa, and still more preferably 120 MPa or more.
- the laminated composite preferably has a flame propagation index Is of 35 or less, more preferably 20 or less, and still more preferably 10 or less, as measured in ASTM-E162.
- Is flame propagation index
- the laminated composite preferably has an optical density Ds (4.0) of smoke after 4 minutes in the smoke density measurement as defined in ASTM-E662 of 200 or less, more preferably 100 or less, still more preferably 50 or less. It is.
- Ds (4.0) is too large, the amount of smoke generated during member combustion increases, which may be inferior in combustion smoke generation as an interior member in an aircraft or a railway vehicle.
- laminated composites described above include but are not limited to infrastructure, aircraft, train sidewall panels, ceiling panels, cargo ships, office dividers, elevator shaft backings, ceiling tiles, embedded housings for lighting fixtures, and current Can be used in building honeycomb sandwich structures, thermoplastic sheets and other such applications that are manufactured using FRP.
- Laminated composites can be formed into a variety of products using methods known in the art, including, for example, pressure forming, thermoforming, hot pressing, vacuum forming, compression molding and autoclave.
- m the weight (g) of the laminated composite
- h the thickness (mm) of the laminated composite.
- the maximum porosity indicates the maximum porosity at which the laminated composite can expand when heated in an unloaded state with respect to the laminated composite before forming. It calculated by measuring the porosity of a laminated composite, after heating the laminated composite before forming in a hot blast furnace set to the forming mold temperature for 5 minutes.
- the thermoplastic resin is an amorphous resin
- the forming temperature is the glass transition temperature of the resin + 30 ° C.
- the thermoplastic resin is a crystalline resin
- the melting point of the resin is + 10 ° C.
- Specific bending strength / Specific bending rigidity Specific bending strength and specific bending rigidity were calculated according to the following formula. Specific bending strength: ⁇ 1/2 / ⁇ Specific bending stiffness: E 1/3 / ⁇
- ⁇ is the bending strength (MPa)
- E is the flexural modulus (GPa)
- ⁇ is the specific gravity of the laminated composite.
- combustion propagation property was evaluated according to ASTM-E162, and the flame propagation index Is was calculated.
- the intrinsic viscosity of the polyester binder fiber was calculated from the solution viscosity measured at 30 ° C. after dissolving in a mixed solution of phenol / chloroethane (weight ratio 1/1).
- PEI polyetherimide
- ULTEM 9001 manufactured by Subic Innovative Plastics
- the PEI polymer was discharged from a round hole nozzle under the conditions of a spinning head temperature of 390 ° C., a spinning speed of 1500 m / min, and a discharge rate of 50 g / min to produce a PEI fiber multifilament of 2640 dtex / 1200 f.
- the obtained multifilament was cut into 15 mm to produce a PEI fiber shortcut fiber.
- the appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 2.2 dtex, and the average fiber length was 15.0 mm.
- the obtained multifilament was crimped and then cut to 51 mm to produce PEI staple fibers.
- the appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 2.2 dtex, and the average fiber length was 51.1 mm.
- the appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 8.8 dtex, and the average fiber length was 15.1 mm. Moreover, after crimping the obtained multifilament, the length was cut to 51 mm to obtain a staple fiber of PEEK fiber. The appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 8.8 dtex, and the average fiber length was 51.0 mm.
- the length was cut to 51 mm to obtain a staple fiber of PC (FR) fiber.
- the appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 2.2 dtex, and the average fiber length was 51.0 mm.
- the length was cut to 51 mm to obtain a staple fiber of PA66 (FR) fiber.
- the appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 0.7 dtex, and the average fiber length was 51.0 mm.
- a multifilament was prepared.
- the obtained multifilament was cut into 15 mm to produce a PC-PBT fiber shortcut fiber.
- the appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 2.2 dtex, and the average fiber length was 15.1 mm.
- the obtained multifilament was crimped and then cut to a length of 51 mm to obtain PC-PBT fiber staple fibers.
- the appearance of the obtained fiber was good without fluff and the like, the average fineness of the single fiber was 2.2 dtex, and the average fiber length was 51.0 mm.
- a multifilament made of a PET polymer of 2640 dtex / 1200 f was obtained by discharging from a round hole nozzle under the conditions of minutes and drawing at a spinning speed of 1200 m / min. The resulting fiber was then cut to 15 mm.
- the appearance of the obtained fiber is good without fluff and the like, the average fineness of the single fiber is 2.2 dtex, the average fiber length is 10.0 mm, the crystallinity is 20%, the intrinsic viscosity is 0.8, and the circular cross-sectional shape Had.
- Example 1 (Skin layer) As a skin layer, a carbon fiber woven fabric having a basis weight of 200 g / m 2 (“W-3101” manufactured by Toho Tenax Co., Ltd.) prepared by laminating a nonwoven fabric made of PEI fibers on both surfaces was prepared.
- Nonwoven fabric made of PEI fibers is made by making 51 mm cut PEI staple fibers into a fabric by needle punching, and producing nonwoven fabrics made of PEI fibers with a basis weight of 100 g / m 2 , a thickness of 0.5 mm, and a bulk density of 0.2 g / cm 3. Was used.
- the core layer comprises 52% by weight of 15 mm cut PEI fibers, 43% by weight of 12.7 mm cut carbon fiber chopped yarn (manufactured by Toho Tenax: average fiber diameter 7 ⁇ m), and 5% by weight of 15 mm cut PET-based binder fibers.
- a nonwoven fabric made of mixed paper with a basis weight of 100 g / m 2 was obtained by a wet raid process, and a laminate of the nonwoven fabrics was prepared.
- the skin layers were arranged one by one on both surfaces of the core layer to produce a laminate in which the layers were not joined to each other.
- the laminated body is heated to 380 ° C. while pressurizing at 15 MPa against a surface perpendicular to the laminating direction with a hot press machine, and the PEI resin constituting the skin layer and the core layer is melted to obtain a skin layer.
- the skin layer and the core were cooled to 200 ° C., which is lower than the glass transition temperature of the PEI, while maintaining the pressure.
- a laminated composite in which the layers were integrated was produced.
- the resulting laminated composite had a thickness of 1.2 mm, a specific gravity of 1.48, a total basis weight of 1800 g / m 2 , a core ratio of 56%, and a porosity of 0%.
- the obtained laminated composite was heated at 300 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 2.7 mm, and the laminated composite was expanded to form a forming mold.
- the thickness of the laminate composite formed was 2.7 mm, the porosity was 54%, and the specific gravity was 0.96.
- SEM scanning electron microscope
- the laminated composite thus formed had a bending strength of 130 MPa, a flexural modulus of 13.0 GPa, a specific bending rigidity of 3.9, and excellent mechanical properties. Further, the combustion propagation property Is was 1, and the smoke density Ds (4.0) was 0.3, and both flame retardancy and low smoke generation were excellent. Furthermore, the maximum porosity was 77%, and the extensibility was excellent.
- Example 2 A laminated composite was produced in the same manner as in Example 1 except that a laminated body in which two skin layers were arranged on each side of the core layer was used.
- the obtained laminated composite had a thickness of 1.8 mm, a specific gravity of 1.49, a total basis weight of 2600 g / m 2 , a core ratio of 38%, and a porosity of 0%.
- the obtained laminated composite was heated at 300 ° C. for 1 minute with a test press machine in which the clearance of the press surface was adjusted to 3.9 mm thickness, and the laminated composite was expanded to form a forming mold.
- the thickness of the laminate composite formed was 3.9 mm, the porosity was 55%, and the specific gravity was 0.96.
- the laminated composite thus formed had a bending strength of 150 MPa, a flexural modulus of 15.2 GPa, a specific bending rigidity of 3.7, and excellent mechanical properties. Further, the combustion propagation property Is was 1, and the smoke concentration Ds (4.0) was 0.2, and both flame retardancy and low smoke generation were excellent. Furthermore, the maximum void ratio was 67%, and the expansibility was excellent.
- Example 3 A laminated composite was produced in the same manner as in Example 1 except that a laminated body in which three skin layers were arranged on both sides of the core layer was used.
- the obtained laminated composite had a thickness of 2.3 mm, a specific gravity of 1.49, a total basis weight of 3400 g / m 2 , a core ratio of 29%, and a porosity of 0%.
- the obtained laminated composite was heated at 300 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 5.1 mm thickness, and the laminated composite was expanded and formed.
- the thickness of the laminate composite formed was 5.1 mm, the porosity was 55%, and the specific gravity was 0.96.
- the laminated composite thus formed had a bending strength of 165 MPa, a flexural modulus of 14.0 GPa, a specific bending rigidity of 3.6, and excellent mechanical properties. Further, the combustion propagation property Is was 1, and the smoke concentration Ds (4.0) was 0.1, and both flame retardancy and low smoke generation were excellent. Furthermore, the maximum porosity was 58%, and the expansibility was excellent.
- Example 4 A laminated composite was produced in the same manner as in Example 1 except that a laminated body in which four skin layers were arranged on each side of the core layer was used.
- the resulting laminated composite had a thickness of 2.8 mm, a specific gravity of 1.49, a total basis weight of 4200 g / m 2 , a core ratio of 24%, and a porosity of 0%.
- the obtained laminated composite was heated at 300 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 6.2 mm thickness, and the laminated composite was expanded to form a forming mold.
- the laminated composite that was formed was not expanded to the set clearance, and the thickness was 4.7 mm.
- the porosity was 40% and the specific gravity was 1.06.
- the laminated composite thus formed had a bending strength of 300 MPa, a flexural modulus of 31.3 GPa, a specific bending rigidity of 3.5, and excellent mechanical properties. Further, the combustion propagation property Is was 1, and the smoke concentration Ds (4.0) was 0.1, and both flame retardancy and low smoke generation were excellent. Furthermore, the maximum porosity was 40%, which was excellent in expansibility.
- Example 5 A laminated composite was produced in the same manner as in Example 2 except that polyether ether ketone (PEEK) fiber was used instead of PEI fiber in the nonwoven fabric constituting the skin layer and the core layer.
- the thickness of the laminated composite in which the skin layer and the core layer were integrated was 1.71 mm, the specific gravity was 1.52, the total basis weight was 2600 g / m 2 , the core ratio was 38%, and the porosity was 0%.
- the obtained laminated composite was heated at 370 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 3.8 mm thickness, and the laminated composite was expanded to form a forming mold.
- the thickness of the laminated composite formed was 3.8 mm, the porosity was 55%, and the specific gravity was 0.98.
- the laminated composite thus formed had a bending strength of 150 MPa, a flexural modulus of 15.2 GPa, a specific bending rigidity of 3.7, and excellent mechanical properties. Further, the combustion propagation property Is was 1, and the smoke density Ds (4.0) was 0.3, and both flame retardancy and low smoke generation were excellent. Furthermore, the maximum porosity was 68%, and the extensibility was excellent.
- Example 6 A laminated composite was produced in the same manner as in Example 2 except that PC (FR) fibers were used for the nonwoven fabric constituting the skin layer and PEI fibers were used for the nonwoven fabric constituting the core layer.
- the thickness of the laminated composite in which the skin layer and the core layer were integrated was 1.7 mm, the specific gravity was 1.49, the total basis weight was 2600 g / m 2 , the core ratio was 39%, and the porosity was 0%.
- the obtained multilayer composite was heated at 300 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 3.8 mm thickness, and the multilayer composite was expanded to form a forming mold.
- the thickness of the laminate composite formed was 3.8 mm, the porosity was 55%, and the specific gravity was 0.96.
- the laminated composite thus formed had a bending strength of 140 MPa, a flexural modulus of 14.8 GPa, a specific bending rigidity of 3.7, and excellent mechanical properties. Further, the combustion propagation property Is was 1, and the smoke density Ds (4.0) was 1.8, which were excellent in both flame retardancy and low smoke generation. Furthermore, the maximum void ratio was 67%, and the expansibility was excellent.
- Example 1 The core layer was not laminated, and eight skin layers described in Example 1 were laminated to produce a laminate.
- the laminated body was heated to 380 ° C. while being pressurized at 10 MPa against a surface perpendicular to the laminating direction with a hot press machine, and the PEI fibers constituting the skin layer were melted, and then the pressure was applied. While maintaining the temperature, it was cooled to 200 ° C., which is lower than the glass transition temperature of PEI, to prepare a laminated composite in which 8 skin layers were integrated.
- the obtained laminated composite had a thickness of 2.1 mm, a specific gravity of 1.50, a total basis weight of 3200 g / m 2 , and a porosity of 0%.
- the laminated composite obtained had a combustion propagation property Is of 1 and a smoke concentration Ds (4.0) of 0.1, which was excellent in both flame retardancy and low smoke generation, but the bending strength was 904 MPa, Although the flexural modulus was 47.9 GPa, the specific flexural rigidity was 2.4, so that the mechanical properties were inferior. Moreover, the maximum porosity of the obtained laminated composite was 5%, which was inferior in expansibility.
- Example 2 The skin layer was not laminated, and 27 core layers described in Example 1 were laminated to produce a laminate.
- the laminated body was heated to 340 ° C. while being pressurized at 15 MPa against a surface perpendicular to the laminating direction with a hot press machine, and the PEI fibers constituting the core layer were melted, and then the pressure was applied. While maintaining the temperature, it was cooled to 200 ° C., which is lower than the glass transition temperature of PEI, to produce a laminated composite in which 27 core layers were integrated.
- the resulting laminated composite had a thickness of 1.8 mm, a specific gravity of 1.47, a total basis weight of 2700 g / m 2 , and a porosity of 0%.
- the laminated composite was heated at 300 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 4.0 mm thickness, and the laminated composite was expanded and formed.
- the thickness of the laminate composite formed was 4.0 mm, the porosity was 55%, and the specific gravity was 0.95.
- the flame propagation property Is of the laminated composite formed was 1 and the smoke concentration Ds (4.0) was 0.5, and both flame retardancy and low smoke generation were excellent.
- the maximum porosity was 85% and it was excellent in expansibility
- the bending strength was 118 MPa and the specific bending rigidity was 3.1, but the bending elastic modulus was 9.3 GPa, so the mechanical properties were improved. It was inferior.
- Example 3 A laminated composite was produced in the same manner as in Example 2 except that PA66 (FR) fiber was used instead of PEI fiber in the nonwoven fabric constituting the skin layer.
- the obtained laminated composite had a thickness of 1.8 mm, a specific gravity of 1.43, a total basis weight of 2600 g / m 2 , a core ratio of 38%, and a porosity of 0%.
- the laminated composite was heated at 300 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 4.1 mm thickness, and the laminated composite was expanded to form a forming mold. Since the obtained laminated composite was inferior in compatibility between the skin layer and the core layer, phase-separated whitened portions were observed.
- the thickness of the laminate composite formed was 3.9 mm, the porosity was 54%, and the specific gravity was 0.92. Although the maximum void ratio of the formed laminate composite was 71% and excellent in expansibility, the bending elastic modulus was 14.3 GPa and the specific bending rigidity was 3.6, but the bending strength was Since it was 95 MPa, it was inferior to a mechanical characteristic.
- Example 4 A laminated composite was produced in the same manner as in Example 2 except that the nonwoven fabric constituting the skin layer and the nonwoven fabric constituting the core layer were replaced with PC-PBT fibers instead of PEI fibers.
- the obtained laminated composite had a thickness of 1.8 mm, a specific gravity of 1.46, a total basis weight of 2600 g / m 2 , a core ratio of 38%, and a porosity of 0%.
- the laminated composite was heated at 300 ° C. for 1 minute in a test press machine in which the clearance of the press surface was adjusted to 4.0 mm thickness, and the laminated composite was expanded and formed.
- the thickness of the laminate composite formed was 4.0 mm, the porosity was 55%, and the specific gravity was 0.94.
- the formed laminate composite has a flexural strength of 150 MPa, a flexural modulus of 15.2 GPa, a specific bending rigidity of 3.7, excellent mechanical properties, and a smoke density Ds (4.0) of 79.
- the maximum porosity was 66%, which was excellent in low smoke generation and expansion, but the combustion propagation Is was 69, which was inferior in flame retardancy.
- PEI is a polyetherimide polymer
- PEEK is a polyetheretherketone polymer
- PC (FR) is a flame retardant-added polycarbonate polymer
- PA66 (FR) is a flame retardant-added polyamide 66 polymer
- PC -PBT is a mixed polymer of a polycarbonate polymer and a polybutylene terephthalate polymer
- CF is a carbon fiber.
- a laminated composite having at least one core layer and at least one skin layer and satisfying all of the following conditions (A) to (D) is excellent in difficulty. In addition to having flammability and low smoke generation performance, it has excellent mechanical properties with excellent integrity. Further, it can be seen that the shape and density can be easily adjusted by heat expansion molding, and the formability is excellent.
- the core layer is a composite in which at least intersections of randomly dispersed non-continuous reinforcing fibers are bonded with a first thermoplastic resin.
- the skin layer is a composite in which continuous reinforcing fibers are impregnated with a second thermoplastic resin.
- the limiting oxygen index of the first and second thermoplastic resins is 30 or more.
- the first and second thermoplastic resins are compatible with each other.
- the laminated composite of the present invention has excellent flame retardancy and low smoke generation performance, can be easily adjusted in shape and density by heat expansion molding, has excellent formability, and has high mechanical properties. Therefore, it is suitable and useful for infrastructure, aircraft, trains, cargo ship side panels, ceiling panels, and the like.
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Abstract
Description
本発明の別の目的は、さらに、加熱膨張成型によって形状及び密度が容易に調整可能で賦形成型性に優れる積層複合体を提供することである。
〔態様1〕
少なくとも1つのコア層と、少なくとも1つのスキン層とを含む積層構造を有し、下記(A)~(D)の条件を全て満たす積層複合体。
(A)前記コア層は、ランダムに分散した非連続強化繊維の少なくとも交点が、第1の熱可塑性樹脂で接着された複合体である。
(B)前記スキン層は、連続強化繊維に、第2の熱可塑性樹脂が含浸した複合体である。
(C)前記第1および前記第2の熱可塑性樹脂の限界酸素指数が30以上(好ましくは32以上、より好ましくは35以上)である。
(D)前記第1および前記第2の熱可塑性樹脂が、互いに相溶である。
〔態様2〕
前記スキン層を構成する連続強化繊維が炭素繊維である、態様1に記載の積層複合体。
〔態様3〕
前記第1および前記第2の熱可塑性樹脂が、それぞれ、ポリエーテルイミド系樹脂、ポリエーテルエーテルケトン系樹脂、ポリエーテルケトンケトン系樹脂、ポリエーテルスルホン系樹脂、熱可塑性ポリイミド系樹脂、難燃剤添加ポリカーボネート系樹脂、および難燃剤添加ポリエステル系樹脂からなる群から選択される少なくとも1つの樹脂である、態様1又は態様2に記載の積層複合体。
〔態様4〕
前記第1および前記第2の熱可塑性樹脂が同一である、態様1~3のいずれか一態様に記載の積層複合体。
〔態様5〕
空隙率が20~80%(好ましくは25~80%、より好ましくは30~80%)である、態様1~4のいずれか一態様に記載の積層複合体。
〔態様6〕
コア層の空隙率が、スキン層の空隙率より2倍以上高い、態様1~5のいずれか一態様に記載の積層複合体。
〔態様7〕
コア層の非連続強化繊維が屈曲しており、さらに膨張させるために用いられる、態様1~4のいずれか一態様に記載の積層複合体。
〔態様8〕
態様1~7のいずれか一態様に記載の積層複合体の製造方法であって、
少なくとも1つのコア層材料と、少なくとも1つのスキン層材料とを積層し、積層体を形成する工程と、
前記積層体を加熱圧縮した後、冷却して前記積層体を一体化する工程とを少なくとも備え、
前記積層体の形成工程において、
前記コア層材料は、非連続強化繊維と、繊維状および/または粒子状の第1の熱可塑性樹脂とで構成され、これらがランダムに分散した不織布であり、
前記スキン層材料は、連続強化繊維からなる布帛と、前記布帛に含浸するための第2の熱可塑性樹脂とで構成され、
前記一体化工程において、
前記第1の熱可塑性樹脂と、前記第2の熱可塑性樹脂が加熱により相溶するとともに、前記非連続強化繊維が屈曲する、積層複合体の製造方法。
〔態様9〕
態様8に記載の一体化工程後に得られた積層複合体を、さらに加熱することで、前記非連続強化繊維の屈曲を解放し、前記積層複合体を膨張させる工程を含む、積層複合体の製造方法。
〔態様10〕
態様7に記載の積層複合体を、加熱することにより前記積層複合体を膨張させる工程を含む、積層複合体の製造方法。
〔態様11〕
前記積層複合体を膨張させる工程において、空隙率が0~20%(好ましくは0~15%、より好ましくは0~10%)の積層複合体を加熱し、加熱後の空隙率が加熱前より大きくなるように膨張させる、態様9または10に記載の積層複合体の製造方法。
〔態様12〕
加熱後の積層複合体の空隙率が20~80%である、態様11に記載の積層複合体の製造方法。
〔態様13〕
前記膨張させる工程が、賦形成型である、態様9~12のいずれか一態様に記載の積層複合体の製造方法。
本発明の積層複合体は、少なくとも1つのコア層と、少なくとも1つのスキン層とを含む積層構造を有し、下記(A)~(D)の条件を全て満たす積層複合体であることが重要である。
(A)前記コア層は、ランダムに分散した非連続強化繊維の少なくとも交点が、第1の熱可塑性樹脂で接着した複合体であること。
(B)前記スキン層は、連続強化繊維に、第2の熱可塑性樹脂が含浸した複合体であること。
(C)前記第1および前記第2の熱可塑性樹脂の限界酸素指数(LOI)が30以上であること。
(D)前記第1および前記第2の熱可塑性樹脂が、互いに相溶であること。
コア層は、ランダムに分散した非連続強化繊維の少なくとも交点が、第1の熱可塑性樹脂で接着した複合体であって、例えば、非連続強化繊維がランダムに交差した構造に、熱可塑性樹脂が部分的、または全体に接着したオープンセル構造を有する複合体で形成される。コア層材料としては、非連続強化繊維と、繊維状及び/又は粒子状の第1の熱可塑性樹脂とを含む不織布を用いてもよい。
高分子バインダーとしては、特に限定されず、例えば、ポリオレフィン系樹脂、ポリアミド系樹脂、ポリエステル系樹脂、アクリル系樹脂、ポリビニルアルコール系樹脂、ポリウレタン系樹脂などが挙げられるが、ポリエステル系樹脂が好ましい。
また、ポリエステル系樹脂を構成するジオール成分としては、エチレングリコールをジオール成分として用いることができるが、エチレングリコール以外の少量の他のジオール成分を、一種または複数種類組み合わせて含んでもよい。
スキン層は、連続強化繊維に第2の熱可塑性樹脂が含浸した複合体であることが重要である。前記連続強化繊維の形態としては、例えば、織物、ノンクリンプファブリック(NCF)、一方向引き揃え材(UD材)、編物などが好適に用いられる。これらの連続強化繊維の形態は、単独でまたは二種以上組み合わせて使用してもよい。好ましくは、強度を向上させる観点から、スキン層は、少なくとも一方向に連続強化繊維が配列する布帛形態であってもよく、例えば、連続強化繊維が経糸または緯糸のいずれか一方向に配列した一方向性織物、連続強化繊維が経糸および緯糸の双方に配列した二方向性織物、連続強化繊維が繊維束として少なくとも一方向に配列するノンクリンプファブリック(NCF)、連続強化繊維が一方向に引き揃えられるUD材などであってもよい。
本発明の積層複合体は、少なくとも1つのコア層と、少なくとも1つのスキン層とを含む積層構造であることが重要である。また、本発明の積層複合体においては、スキン層とコア層の間の接着性を高め、積層複合体に軽量性かつ高い曲げ弾性率を付与する観点から、前記第1および前記第2の熱可塑性樹脂が互いに相溶であることが重要である。
相溶性を有する限り、第1の熱可塑性樹脂および第2の熱可塑性樹脂は、自由に組み合わせることができるが、第1の熱可塑性樹脂と第2の熱可塑性樹脂とは、互いに同種の樹脂であることが好ましい。相溶性のある樹脂の組み合わせとしては、例えば、ポリエーテルイミド系樹脂とポリカーボネート系樹脂(好ましくは難燃剤添加ポリカーボネート系樹脂)、ポリエーテルイミド系樹脂とポリエーテルエーテルケトン系樹脂、ポリエーテルエーテルケトン系樹脂とポリエーテルケトンケトン系樹脂、ポリエーテルイミド系樹脂と難燃剤添加ポリエステル系樹脂などが挙げられる。
また、積層体の形成工程において、前記スキン層材料は、連続強化繊維からなる布帛と、前記布帛に含浸するための第2の熱可塑性樹脂とで構成されていてもよく、第2の熱可塑性樹脂が含浸する前の前駆体であってもよいし、含浸した複合体であってもよい。
なお、コア層とスキン層の空隙率は、それぞれ、積層複合体を切断し、コア層のみの部分とスキン層のみのサンプルを得た後、それぞれの切断部分について空隙率を求めればよい。
積層複合体の比重は、1cm×10cmの短冊状に切り出した積層複合体の厚みと重量から、下記の式に従って算出し、10本分の平均を求めた。
比重=(m×10)/(1×10×h)
なお、ここでmは積層複合体の重量(g)、hは積層複合体の厚み(mm)である。
JIS K 7075に従い、燃焼法によって繊維重量含有率を求め、これと積層複合体の比重から積層複合体の空隙率を求めた。
なお、コア層およびスキン層の空隙率を別々に求める場合、積層複合体から、ランダムにコア層およびスキン層のサンプルを採取し、それぞれのサンプルについて、上述の方法により、空隙率を求めた。
最大空隙率は、賦形成型する前の積層複合体について、負荷をかけない状態において加熱した場合に、積層複合体が膨張することができる最大の空隙率を示すものであり、次に定義される賦形成型温度に設定した熱風炉にて賦形成型する前の積層複合体を5分間加熱した後、積層複合体の空隙率を測定することで算出した。前記賦形成型温度は、熱可塑性樹脂が非晶性樹脂の場合はその樹脂のガラス転移温度+30℃で、結晶性樹脂の場合はその樹脂の融点+10℃である。
曲げ強度(σ)・弾性率(E)はJIS K 7017(A法・クラスI試験片)に準拠して評価を行った。
比曲げ強度、比曲げ剛性は下記式に従って算出した。
比曲げ強度:σ1/2/ρ
比曲げ剛性:E1/3/ρ
なお、ここでσは曲げ強度(MPa)、Eは曲げ弾性率(GPa)、ρは積層複合体の比重である。
燃焼伝播性はASTM-E162に準拠して評価を行い、火炎伝播指数Isを算出した。
煙濃度はASTM-E662に準拠して評価を行い、4分後の煙の光学濃度Ds(4.0)を算出した。
ポリエステル系バインダー繊維の結晶化度は、広角X線回折法により求めた。すなわち、(株)リガク製X線発生装置(RAD-3A型)を用い、ニッケルフィルターで単色化したCu-Kα線で[010]の散乱強度を測定し、次式により結晶化度を算出した。
(結晶化度Xc)=(結晶部の散乱強度)/(全散乱強度)×100(%)
ポリエステル系バインダー繊維の固有粘度は、フェノール/クロロエタン(重量比1/1)の混合溶液に溶解させ、30℃で測定した溶液粘度から算出した。
コア層の断面観察は、得られた積層複合体を切断し、走査型電子顕微鏡(JEOL製JSM-5300)を用いて、その切断面を観察した。
非晶性樹脂であるポリエーテルイミド(以下、PEIと略称することがある)系ポリマー(サビックイノベーティブプラスチックス社製「ULTEM9001」)を150℃で12時間真空乾燥した。前記PEI系ポリマーを紡糸ヘッド温度390℃、紡糸速度1500m/分、吐出量50g/分の条件で丸孔ノズルより吐出し、2640dtex/1200fのPEI系繊維のマルチフィラメントを作製した。得られたマルチフィラメントを15mmにカットし、PEI繊維のショートカットファイバーを作製した。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は2.2dtex、平均繊維長は15.0mmであった。
また、上記の繊維長15.0mmのPEI繊維のショートカットファイバーとは別に、得られたマルチフィラメントを捲縮加工した後、長さを51mmにカットし、PEI繊維のステープル繊維を作製した。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は2.2dtex、平均繊維長は51.1mmであった。
ポリエーテルエーテルケトン(以降PEEKと略称することがある)系ポリマー(Victrex社製「90G」)を80℃で12時間真空乾燥した。前記PEEK系ポリマーを紡糸ヘッド温度400℃、紡糸速度1500m/分、吐出量50g/分の条件で丸孔ノズルより吐出し、マルチフィラメントを作製した。得られたマルチフィラメントを15mmにカットし、PEEK繊維のショートカットファイバーを作製した。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は8.8dtex、平均繊維長は15.1mmであった。
また、得られたマルチフィラメントを捲縮加工した後、長さを51mmにカットし、PEEK繊維のステープルファイバーを得た。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は8.8dtex、平均繊維長は51.0mmであった。
難燃剤添加ポリカーボネート系ポリマー(サビックイノベーティブプラスチックス社製「LEXAN FST9705」、以下PC(FR)と略称することがある)を105℃で12時間真空乾燥した。前記PC(FR)系ポリマーを紡糸ヘッド温度310℃、紡糸速度1500m/分、吐出量50g/分の条件で丸孔ノズルより吐出し、2640dtex/1200fのPC(FR)繊維のマルチフィラメントを作製した。得られたマルチフィラメントを捲縮加工した後、長さを51mmにカットし、PC(FR)繊維のステープルファイバーを得た。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は2.2dtex、平均繊維長は51.0mmであった。
難燃剤添加ポリアミド66系ポリマー(旭化成社製「レオナFR370」、以下PA66(FR)と略称することがある)を80℃で12時間真空乾燥した。前記半芳香族ポリアミド系ポリマーを紡糸ヘッド温度310℃、紡糸速度1500m/分、吐出量50g/分の条件で丸孔ノズルより吐出し、PA66(FR)繊維のマルチフィラメントを作製した。得られたマルチフィラメントを捲縮加工した後、長さを51mmにカットし、PA66(FR)繊維のステープルファイバーを得た。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は0.7dtex、平均繊維長は51.0mmであった。
ポリカーボネートポリマー(サビックイノベーティブプラスチックス社製「LEXAN121R」)67重量%とポリブチレンテレフタラートポリマー(サビックイノベーティブプラスチックス社製「VALOX325」)33重量%を混合し、120℃で4時間真空乾燥した。前記ポリマーを紡糸ヘッド温度280℃、紡糸速度1500m/分、吐出量50g/分の条件で丸孔ノズルより吐出し、ポリカーボネート/ポリブチレンテレフタラート(以下、PC-PBTと略称することがある)繊維のマルチフィラメントを作製した。得られたマルチフィラメントを15mmにカットし、PC-PBT繊維のショートカットファイバーを作製した。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は2.2dtex、平均繊維長は15.1mmであった。
また、得られたマルチフィラメントを捲縮加工した後、長さを51mmにカットし、PC-PBT繊維のステープルファイバーを得た。得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は2.2dtex、平均繊維長は51.0mmであった。
重合反応装置を用い、常法により280℃で重縮合反応を行い、テレフタル酸とイソフタル酸の共重合割合(モル比)が70/30、エチレングリコール100モル%からなる、固有粘度(η)が0.81であるPET系ポリマーを製造した。製造されたポリマーは、重合機底部よりストランド状に水中に押し出し、ペレット状に切断した。得られたPET系ポリマーを、270℃で加熱された同方向回転タイプのベント式2軸押し出し機に供給し、滞留時間2分を経て280℃に加熱された紡糸ヘッドに導き、吐出量45g/分の条件で丸孔ノズルより吐出し、紡糸速度1200m/分で引き取ることで2640dtex/1200fのPET系ポリマーからなるマルチフィラメントを得た。次いで得られた繊維を15mmにカットした。
得られた繊維の外観は毛羽等なく良好で、単繊維の平均繊度は2.2dtex、平均繊維長は10.0mm、結晶化度は20%、固有粘度は0.8、および円形の断面形状を有していた。
(スキン層)
スキン層として、目付200g/m2の炭素繊維織物(東邦テナックス社製「W-3101」)に対して、PEI繊維からなる不織布を両面に積層したものを準備した。PEI繊維からなる不織布は、51mmカットのPEIステープルファイバーをニードルパンチ法により布帛化し、目付100g/m2、厚み0.5mm、かさ密度0.2g/cm3のPEI繊維からなる不織布を作製したものを用いた。
コア層として、15mmカットのPEI繊維52重量%、12.7mmカットの炭素繊維チョップド糸(東邦テナックス製:平均繊維径7μm)を43重量%、15mmカットのPET系バインダー繊維を5重量%からなるスラリーを用いて、ウェットレイドプロセスにより目付100g/m2の混抄紙からなる不織布を得、前記不織布を積層したものを準備した。
前記コア層の両面に前記スキン層を1層ずつ配して、各層同士が接合していない積層体を作製した。前記積層体を熱プレス機にて、積層方向に対して垂直な面に対して15MPaにて加圧しながら、380℃に加熱し、スキン層及びコア層を構成するPEI樹脂を溶融させ、スキン層の連続強化繊維の間及びコア層の非連続強化繊維の間にPEI樹脂を含浸させた後、加圧を維持したまま、PEIのガラス転移温度以下である200℃まで冷却し、スキン層及びコア層を一体化させた積層複合体を作製した。得られた積層複合体の厚みは1.2mm、比重は1.48、総目付は1800g/m2、コア比率は56%、空隙率は0%であった。
得られた積層複合体を、プレス面のクリアランスを2.7mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体の厚みは2.7mm、空隙率は54%、比重は0.96であった。また、コア層の断面の走査型電子顕微鏡(SEM)写真(図1及び2)を取得し、コア層がランダムに分散した非連続強化繊維からなる不織布の交点が熱可塑性樹脂で接着している様子を確認した。賦形成型させた積層複合体の曲げ強度は130MPa、曲げ弾性率は13.0GPa、比曲げ剛性は3.9であり、力学特性に優れるものであった。また、燃焼伝播性Isは1で、煙濃度Ds(4.0)は0.3であり、難燃性、低発煙性ともに優れるものであった。さらに、最大空隙率は77%であり、膨張性に優れるものであった。
コア層の両面にスキン層を2層ずつ配した積層体とした以外は実施例1と同様にし、積層複合体を作製した。得られた積層複合体の厚みは1.8mm、比重は1.49、総目付は2600g/m2、コア比率は38%、空隙率は0%であった。得られた積層複合体を、プレス面のクリアランスを3.9mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体の厚みは3.9mm、空隙率は55%、比重は0.96であった。賦形成型させた積層複合体の曲げ強度は150MPa、曲げ弾性率は15.2GPa、比曲げ剛性は3.7であり、力学特性に優れるものであった。また、燃焼伝播性Isは1で、煙濃度Ds(4.0)は0.2であり、難燃性、低発煙性ともに優れるものであった。さらに、最大空隙率は67%であり、膨張性に優れるものであった。
コア層の両面にスキン層を3層ずつ配した積層体とした以外は実施例1と同様にし、積層複合体を作製した。得られた積層複合体の厚みは2.3mm、比重は1.49、総目付は3400g/m2、コア比率は29%、空隙率は0%であった。得られた積層複合体を、プレス面のクリアランスを5.1mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体の厚みは5.1mm、空隙率は55%、比重は0.96であった。賦形成型させた積層複合体の曲げ強度は165MPa、曲げ弾性率は14.0GPa、比曲げ剛性は3.6であり、力学特性に優れるものであった。また、燃焼伝播性Isは1で、煙濃度Ds(4.0)は0.1であり、難燃性、低発煙性ともに優れるものであった。さらに、最大空隙率は58%であり、膨張性に優れるものであった。
コア層の両面にスキン層を4層ずつ配した積層体とした以外は実施例1と同様にし、積層複合体を作製した。得られた積層複合体の厚みは2.8mm、比重は1.49、総目付は4200g/m2、コア比率は24%、空隙率は0%であった。得られた積層複合体を、プレス面のクリアランスを6.2mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体は設定したクリアランスまで膨張せず、厚みが4.7mmであった。空隙率は40%、比重は1.06であった。賦形成型させた積層複合体の曲げ強度は300MPa、曲げ弾性率は31.3GPa、比曲げ剛性は3.5であり、力学特性に優れるものであった。また、燃焼伝播性Isは1で、煙濃度Ds(4.0)は0.1であり、難燃性、低発煙性ともに優れるものであった。さらに、最大空隙率は40%であり、膨張性に優れるものであった。
スキン層を構成する不織布およびコア層を形成する不織布において、PEI繊維の代わりにポリエーテルエーテルケトン(PEEK)繊維を用いた以外は実施例2と同様にし、積層複合体を作製した。スキン層およびコア層を一体化させた積層複合体の厚みは1.71mm、比重は1.52、総目付は2600g/m2、コア比率は38%、空隙率は0%であった。得られた積層複合体を、プレス面のクリアランスを3.8mm厚に調整したテストプレス機にて370℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体の厚みは3.8mm、空隙率は55%、比重は0.98であった。賦形成型させた積層複合体の曲げ強度は150MPa、曲げ弾性率は15.2GPa、比曲げ剛性は3.7であり、力学特性に優れるものであった。また、燃焼伝播性Isは1で、煙濃度Ds(4.0)は0.3であり、難燃性、低発煙性ともに優れるものであった。さらに、最大空隙率は68%であり、膨張性に優れるものであった。
スキン層を構成する不織布にPC(FR)繊維を用い、コア層を構成する不織布にPEI繊維を用いた以外は実施例2と同様にし、積層複合体を作製した。スキン層およびコア層を一体化させた積層複合体の厚みは1.7mm、比重は1.49、総目付は2600g/m2、コア比率は39%、空隙率は0%であった。得られた積層複合体を、プレス面のクリアランスを3.8mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体の厚みは3.8mm、空隙率は55%、比重は0.96であった。賦形成型させた積層複合体の曲げ強度は140MPa、曲げ弾性率は14.8GPa、比曲げ剛性は3.7であり、力学特性に優れるものであった。また、燃焼伝播性Isは1で、煙濃度Ds(4.0)は1.8であり、難燃性、低発煙性ともに優れるものであった。さらに、最大空隙率は67%であり、膨張性に優れるものであった。
コア層は積層させず、実施例1に記載のスキン層を8層積層させ、積層体を作製した。前記積層体を熱プレス機にて、積層方向に対して垂直な面に対して10MPaにて加圧しながら、380℃に加熱し、スキン層を構成するPEI繊維を溶融させた後、加圧を維持したまま、PEIのガラス転移温度以下である200℃まで冷却し、スキン層8層を一体化させた積層複合体を作製した。得られた積層複合体の厚みは2.1mm、比重は1.50、総目付は3200g/m2、空隙率は0%であった。得られた積層複合体の燃焼伝播性Isは1で、煙濃度Ds(4.0)は0.1であり、難燃性、低発煙性ともに優れるものであったが、曲げ強度は904MPa、曲げ弾性率は47.9GPaであるものの、比曲げ剛性が2.4であるため力学特性に劣るものであった。また、得られた積層複合体の最大空隙率は5%であり、膨張性に劣るものであった。
スキン層は積層せず、実施例1に記載のコア層を27層積層させ、積層体を作製した。前記積層体を熱プレス機にて、積層方向に対して垂直な面に対して15MPaにて加圧しながら、340℃に加熱し、コア層を構成するPEI繊維を溶融させた後、加圧を維持したまま、PEIのガラス転移温度以下である200℃まで冷却し、コア層27層を一体化させた積層複合体を作製した。得られた積層複合体の厚みは1.8mm、比重は1.47、総目付は2700g/m2、空隙率は0%であった。積層複合体を、プレス面のクリアランスを4.0mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体の厚みは4.0mm、空隙率は55%、比重は0.95であった。賦形成型させた積層複合体の燃焼伝播性Isは1で、煙濃度Ds(4.0)は0.5であり、難燃性、低発煙性ともに優れるものであった。また、最大空隙率は85%であり、膨張性に優れるものであったが、曲げ強度は118MPaで、比曲げ剛性は3.1であるものの、曲げ弾性率9.3GPaであるため力学特性に劣るものであった。
スキン層を構成する不織布において、PEI繊維の代わりにPA66(FR)繊維を用いた以外は実施例2と同様にし、積層複合体を作製した。得られた積層複合体の厚みは1.8mm、比重は1.43、総目付は2600g/m2、コア比率は38%、空隙率は0%であった。積層複合体を、プレス面のクリアランスを4.1mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。得られた積層複合体は、スキン層とコア層との相溶性に劣るため、相分離した白化箇所が見られた。賦形成型させた積層複合体の厚みは3.9mm、空隙率は54%、比重は0.92であった。賦形成型させた積層複合体の最大空隙率は71%であり、膨張性に優れるものであったが、曲げ弾性率は14.3GPa、比曲げ剛性は3.6であるものの、曲げ強度が95MPaであるため力学特性に劣るものであった。
スキン層を構成する不織布およびコア層を構成する不織布において、PEI繊維の代わりにPC-PBT繊維を用いた以外は実施例2と同様にし、積層複合体を作製した。得られた積層複合体の厚みは1.8mm、比重は1.46、総目付は2600g/m2、コア比率は38%、空隙率は0%であった。積層複合体を、プレス面のクリアランスを4.0mm厚に調整したテストプレス機にて300℃で1分間加熱し、積層複合体を膨張させ、賦形成型させた。賦形成型させた積層複合体の厚みは4.0mm、空隙率は55%、比重は0.94であった。賦形成型させた積層複合体の曲げ強度は150MPa、曲げ弾性率は15.2GPa、比曲げ剛性は3.7であり、力学特性に優れるものであるとともに、煙濃度Ds(4.0)は79、最大空隙率は66%であり、低発煙性、膨張性に優れるものであったが、燃焼伝播性Isは69で、難燃性に劣るものであった。
(A)前記コア層は、ランダムに分散した非連続強化繊維の少なくとも交点が、第1の熱可塑性樹脂で接着された複合体である。
(B)前記スキン層は、連続強化繊維に、第2の熱可塑性樹脂が含浸した複合体である。
(C)前記第1および前記第2の熱可塑性樹脂の限界酸素指数が30以上である。
(D)前記第1および前記第2の熱可塑性樹脂が、互いに相溶である。
したがって、そのような変更および修正は、請求の範囲から定まる発明の範囲内のものと解釈される。
Claims (13)
- 少なくとも1つのコア層と、少なくとも1つのスキン層とを含む積層構造を有し、下記(A)~(D)の条件を全て満たす積層複合体。
(A)前記コア層は、ランダムに分散した非連続強化繊維の少なくとも交点が、第1の熱可塑性樹脂で接着された複合体である。
(B)前記スキン層は、連続強化繊維に、第2の熱可塑性樹脂が含浸した複合体である。
(C)前記第1および前記第2の熱可塑性樹脂の限界酸素指数が30以上である。
(D)前記第1および前記第2の熱可塑性樹脂が、互いに相溶である。 - 前記スキン層を構成する連続強化繊維が炭素繊維である、請求項1に記載の積層複合体。
- 前記第1および前記第2の熱可塑性樹脂が、それぞれ、ポリエーテルイミド系樹脂、ポリエーテルエーテルケトン系樹脂、ポリエーテルケトンケトン系樹脂、ポリエーテルスルホン系樹脂、熱可塑性ポリイミド系樹脂、難燃剤添加ポリカーボネート系樹脂、および難燃剤添加ポリエステル系樹脂からなる群から選択される少なくとも1つの樹脂である、請求項1又は請求項2に記載の積層複合体。
- 前記第1および前記第2の熱可塑性樹脂が同一である、請求項1~3のいずれか一項に記載の積層複合体。
- 空隙率が20~80%である、請求項1~4のいずれか一項に記載の積層複合体。
- コア層の空隙率が、スキン層の空隙率より2倍以上高い、請求項1~5のいずれか一項に記載の積層複合体。
- コア層の非連続強化繊維が屈曲しており、さらに膨張させるために用いられる、請求項1~4のいずれか一項に記載の積層複合体。
- 請求項1~7のいずれか一項に記載の積層複合体の製造方法であって、
少なくとも1つのコア層材料と、少なくとも1つのスキン層材料とを積層し、積層体を形成する工程と、
前記積層体を加熱圧縮した後、冷却して前記積層体を一体化する工程とを少なくとも備え、
前記積層体の形成工程において、
前記コア層材料は、非連続強化繊維と、繊維状および/または粒子状の第1の熱可塑性樹脂とで構成され、これらがランダムに分散した不織布であり、
前記スキン層材料は、連続強化繊維からなる布帛と、前記布帛に含浸するための第2の熱可塑性樹脂とで構成され、
前記一体化工程において、
前記第1の熱可塑性樹脂と、前記第2の熱可塑性樹脂が加熱により相溶するとともに、前記非連続強化繊維が屈曲する、積層複合体の製造方法。 - 請求項8に記載の一体化工程後に得られた積層複合体を、さらに加熱することで、前記非連続強化繊維の屈曲を解放し、前記積層複合体を膨張させる工程を含む、積層複合体の製造方法。
- 請求項7に記載の積層複合体を、加熱することにより前記積層複合体を膨張させる工程を含む、積層複合体の製造方法。
- 前記積層複合体を膨張させる工程において、空隙率が0~20%の積層複合体を加熱し、加熱後の積層複合体の空隙率が、加熱前より大きくなるように膨張させる、請求項9または10に記載の積層複合体の製造方法。
- 加熱後の積層複合体の空隙率が20~80%である、請求項11に記載の積層複合体の製造方法。
- 前記膨張させる工程が、賦形成型である、請求項9~12のいずれか一項に記載の積層複合体の製造方法。
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- 2018-04-24 JP JP2019514532A patent/JP7066686B2/ja active Active
- 2018-04-24 EP EP18791292.8A patent/EP3616902A4/en active Pending
- 2018-04-24 CN CN201880028094.XA patent/CN110603145B/zh active Active
- 2018-04-24 WO PCT/JP2018/016612 patent/WO2018199091A1/ja active Application Filing
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Cited By (12)
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JPWO2019107343A1 (ja) * | 2017-11-28 | 2020-12-17 | 株式会社クラレ | 耐火部材 |
EP3719060A4 (en) * | 2017-11-28 | 2021-09-01 | Kuraray Co., Ltd. | FIRE-RESISTANT MATERIAL |
JP7216010B2 (ja) | 2017-11-28 | 2023-01-31 | 株式会社クラレ | 耐火部材 |
US11718718B2 (en) | 2017-11-28 | 2023-08-08 | Kuraray Co., Ltd. | Refractory material |
WO2020183945A1 (ja) * | 2019-03-13 | 2020-09-17 | 株式会社クラレ | 空間充填材および空間充填構造体、ならびにそれらの使用方法 |
JPWO2020183945A1 (ja) * | 2019-03-13 | 2020-09-17 | ||
JP7129550B2 (ja) | 2019-03-13 | 2022-09-01 | 株式会社クラレ | 空間充填材および空間充填構造体、ならびにそれらの使用方法 |
EP4036287A4 (en) * | 2019-09-27 | 2024-04-17 | Kuraray Co., Ltd. | POLYCARBONATE FIBERS, FIBER STRUCTURE AND RESIN COMPOSITES |
JP2021123102A (ja) * | 2020-02-07 | 2021-08-30 | 南亞塑膠工業股▲分▼有限公司 | レーザーエンボス用ポリエステルフィルム及びその製造方法 |
JP7445514B2 (ja) | 2020-05-25 | 2024-03-07 | 株式会社クラレ | 空間充填材および空間充填構造体 |
CN113955096A (zh) * | 2021-10-09 | 2022-01-21 | 中国直升机设计研究所 | 一种无人倾转旋翼机横向机动控制方法 |
CN113955096B (zh) * | 2021-10-09 | 2023-06-27 | 中国直升机设计研究所 | 一种无人倾转旋翼机横向机动控制方法 |
Also Published As
Publication number | Publication date |
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US20200055276A1 (en) | 2020-02-20 |
CN110603145A (zh) | 2019-12-20 |
EP3616902A4 (en) | 2021-01-06 |
WO2018199091A8 (ja) | 2019-11-07 |
TW201843038A (zh) | 2018-12-16 |
JPWO2018199091A1 (ja) | 2020-03-12 |
JP7066686B2 (ja) | 2022-05-13 |
EP3616902A1 (en) | 2020-03-04 |
US11370195B2 (en) | 2022-06-28 |
CN110603145B (zh) | 2022-01-11 |
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