METHOD OF PREPARATION OF NANOFIBRYL POLYMER COMPOSITES AND COMPOSITE MATERIAL

专利摘要:
nanofibril polymer composites The present invention relates, among other things, to compositions comprising nanofibrils, of at least one maleic anhydride (ma) copolymer and at least one matrix polymer, and methods of producing such compositions. the provided methods and compositions allow for the production of composites with unexpectedly superior properties including improved impact strength, tensile modulus of elasticity, tensile strength, and flexural modulus of elasticity as compared to previously known composites. in some embodiments, the present invention provides methods including the steps of providing the cellulose nanofibrils, associating the cellulose nanofibrils with a maleic anhydride (ma) copolymer to form a nanofibrilam copolymer blend, preparing the copolymer blend of nanofibrilma for addition to a matrix polymer, and formation of a composite by associating the nanofibril ma copolymer mixture with the matrix polymer, in which the amount of cellulose nanofibrils in the composite is between 3% and 50 % by weight of the composite.
公开号:BR112016000813B1
申请号:R112016000813-8
申请日:2014-07-17
公开日:2021-08-03
发明作者:Douglas J. Gardner；Yousoo Han；Yucheng Peng
申请人:University Of Maine System Board Of Trustees；
IPC主号:

专利说明:

Cross Reference to Related Orders
[001] The present invention relates to the application claiming priority to United States Provisional Patent Application serial number 61/847,751, filed July 18, 2013, the description of which is incorporated herein by reference in its entirety. Public financing
[002] This invention was made with government support under grant number CSREES ME09615-08MS, judged by the U.S. Department of Agriculture. The government has certain rights in the invention. Background
[003] The development of composite materials, including polymer composite materials, have been an area of intense research. In part, the development of these new materials is attractive because polymer composites, for example, reinforced by various fillers or additives, can be developed to exhibit desirable or improved mechanical properties useful in industries, but not limited to construction industries, transportation, industrial, and consumer application. summary
[004] The present invention provides, among other things, composite materials comprising nanofibrils, a maleic anhydride (MA) copolymer and a matrix polymer, and methods of producing such compositions. The methods provided and composite materials exhibit unexpectedly superior properties including improved impact strength, tensile modulus of elasticity, tensile strength, and flexural modulus of elasticity, as compared to previously known composites.
[005] In some embodiments, the present invention provides the methods including the steps of supplying the cellulose nanofibrils, association of the cellulose nanofibrils with a copolymer of maleic anhydride (MA) to form a mixture of nanofibril-MA copolymer, preparation of the nanofibril-MA copolymer mixture for addition to a matrix polymer, and formation of a composite by associating the nanofibril-MA copolymer mixtures with the matrix polymer, where the amount of cellulose nanofibrils in the composite is between 3% and 50% by weight of the composite. In some embodiments, the preparation step comprises drying the nanofibril-MA copolymer blend. In some embodiments, drying is spray drying.
[006] According to various embodiments, the preparation of a nanofibril-MA copolymer mixture for addition to a matrix polymer can take any suitable form of application. In some embodiments, the preparation step includes drying the nanofibril-MA copolymer blend, cooling the nanofibril-MA copolymer dry blend, and granulating the nanofibril-MA copolymer dry blend to form a master batch of nanofibril-MA copolymer.
[007] It is considered that the conditions under which the association step occurs may vary according to the desired shape and properties of the desired material of the composite. In some modalities, the association step takes place at a temperature between 130°C and 220°C, inclusive. In some modalities, the association step comprises the mixing of cellulose nanofibrils and maleic anhydride (MA) copolymer for between 1 minute and 60 minutes, inclusive.
[008] The compositions and methods provided, in accordance with various embodiments, may include the use of substantially dry components (e.g., nanofibrils, MA copolymers, and matrix polymers) and/or the use of one or more components that they are not dry, like the components in the solution. In some modalities, the cellulose nanofibrils are in solution at the time of initiation of the association step. In some embodiments, the maleic anhydride copolymer comprises the dispersed phase of an emulsion at the time of initiation of the association step. In some embodiments, the cellulose nanofibrils are substantially dry at the time of initiation of the association step. As used herein the term "substantially dry" means the nanofibrils (or other component) contain less than 1% moisture content based on the oven dry weight of the nanofibrils (or other component).
[009] As described here, several embodiments provide the composites with improved properties. In some embodiments, the composites provided are characterized as having an impact strength that is greater than that of a composite consisting of the matrix polymer and the cellulose nanofibrils. In some embodiments, the impact strength of the composite is at least 20% (eg 25%, 30%, 35%, 40%, 45%, or 50%) greater than that of a composite consisting of the matrix polymer and cellulose nanofibrils.
[0010] In some embodiments, the composites provided are characterized as having a tensile modulus of elasticity at least 35% greater than that of a composite consisting of the matrix polymer and the cellulose nanofibrils. In some embodiments, the composites provided are characterized as having tensile strength at least 10% greater than that of a composite consisting of the matrix polymer and the cellulose nanofibrils.
[0011] Any one of a variety of maleic anhydride copolymers is considered to be within the scope of the present invention. In some embodiments, a maleic anhydride polymer is selected from an olefin polymer of maleic anhydride and a polystyrene maleic anhydride. In some embodiments, an olefin maleic anhydride copolymer is maleic anhydride polypropylene or polyethylene maleic anhydride.
[0012] Those of versatility in the art will recognize that there are a variety of ways to form composite materials. According to various embodiments, the composites provided can be formed by any of a variety of processes. In some embodiments, a composite is formed through an extrusion, compression molding, injection molding, and/or cast layer molding process (eg, 3D printing).
[0013] The present invention also provides composite materials with improved properties. In some embodiments, the composite material is produced according to one of the methods described herein.
[0014] As used in this application, the terms "about" and "approximately" are used as equivalents. Any citations to publications, patents, or patent applications herein are incorporated by reference in their entirety. Any numerals employed in this application with or without approximately/approximately are intended to cover any normal variations appreciated by one of ordinary versatility in the relevant art.
[0015] Other features, objects, and advantages of the present invention are evident from the detailed description that follows. It is to be understood, however, that the detailed description, while indicating the embodiments of the present invention, is given by way of illustration only, not limitation. Various changes and modifications within the scope of the invention should become apparent to those skilled in the art from the detailed description. Brief Description of Drawings
[0016] The figures described below, which together produce the Drawing, are for illustrative purposes only, and are not by way of limitation.
[0017] Figure 1 shows a flow diagram representing certain exemplary modalities.
[0018] Figure 2 shows a graph of the particle size distributions (PSD) of exemplary cellulose nanofibrils (CNFs) in suspension or dry form. CNF represents the PSD of spray-dried CNF. MAPP_CNF represents the PSD of spray dried CNFs treated by MAPP emulsion. CNF_1 represents the original PSD of the CNFs in suspension. CNF_2 represents the PSD of the mixture of CNFs and MAPP emulsion before ultrasonic treatment. CNF_3 represents the PSD of the mixture of CNFs and MAPP emulsion after ultrasonic treatment. MAPP indicates the PSD of solids content in the MAPP emulsion.
[0019] Figures 3A-B show exemplary SEM micrograms of spray dried CNFs: panel (A) x 200 and panel (B) x 1000.
[0020] Figure 4 shows an exemplary graph of the modulus of elasticity and tensile strength of certain modalities as tested in accordance with ASTM D 638-10.
Figures 5A-F show exemplary SEM micrograms of composites comprising PP and/or PP + MAPP. Panel A: Fractured specimen surface, Panel B: Fractured specimen cross-section, Panels C, D, E, and F: show exemplary regions 1, 2, 3, and 4 in specimen cross-section.
[0022] Figures 6A-F show exemplary SEM micrograms of CNF-reinforced PP. Panel A: PP + MAPP_CNF, panels B and C: PP + CNF, panel D: PP + MAPP_CNF, panels E and F: PP + MAPP + CNF.
[0023] Figure 7 shows an exemplary graph of the modulus of elasticity and tensile strength of certain modalities as tested in accordance with ASTM D 790-10.
[0024] Figure 8 shows a graph of the impact resistance of certain modalities.
[0025] Figures 9A-F show cross-sections of the exemplary fracture of certain modalities after impact testing at 120X, 200X, or 2000X magnification. Panels A and B: PP, panels C and D: PP + CNF, panels E and F: PP + MAPP_CNF.
[0026] Figures 10A-F show cross-sections of the exemplary fracture of certain modalities after impact testing at 120X, 200X, 5,000X, or 10,000X magnification. Panels A, C, and E: PP + MAPP, panels B, D, and F: PP + MAPP + CNF.
[0027] Figures 11A-C show the graphs of the mechanical properties of certain embodiments comprising polypropylene reinforced by cellulose nanoparticle (CNP) (6% CNP loading). Panel A shows the tensile modulus and tensile strength of certain modalities, panel B shows the flexural modulus and strength of certain modalities, and panel C shows the impact strength of certain modalities.
[0028] Figure 12 shows a graph of the increase in certain traction properties exhibited by certain modalities.
[0029] Figure 13 shows a graph of the increase in certain flexural properties exhibited by certain modalities.
[0030] Figure 14 shows a graph of the increase in impact strength exhibited by certain modalities. Definitions
[0031] In this application, unless otherwise clear from the context, (i) the term "one" may be understood to mean "at least one"; (ii) the term “or” can be understood to mean “and/or”; (iii) the terms “comprising” and “including” may be understood to encompass the detailed steps or components whether presented alone or together with one or more additional steps or components; and (iv) the terms "about" and "approximately" may be understood to allow for standard variation as would be understood by those of ordinary versatility in the art; and (v) where extensions are provided, purposes are included.
[0032] Approximately: As used herein, the term "approximately" and "about" is intended to encompass normal statistical variation as would be understood by those of ordinary versatility in the technique. In certain modalities, the term "approximately" or "about" refers to a range of values that fall within 25%, 20%, 19%, 18%, 17%, 16%, 15%, 14%, 13 %, 12%, 11%, 10%, 9%, 8%, 7%, 6%, 5%, 4%, 3%, 2%, 1%, or less in another direction (greater than or less than that) of the established reference value unless otherwise stated or otherwise evident from the context (except where such number would exceed 100% of a possible value).
[0033] Substantially: As used herein, the term "substantially" refers to the qualitative condition of displaying the degree or almost total or total extent of a characteristic or property of interest. One of ordinary versatility in technique will understand that chemical phenomena rarely, if ever, go to completion and/or proceed to integrity or achieve or avoid an absolute result. The term “substantially” is therefore used here to capture the potential lack of integrity inherent in many chemical phenomena. Detailed Description of Certain Modalities
[0034] The present invention provides, among other things, composite materials with improved properties, and methods of producing these materials. In some embodiments, the composite materials provided comprise nanofibrils, a maleic anhydride (MA) copolymer, and a matrix polymer. According to various embodiments, the methods provided and composite materials exhibit unexpectedly superior properties including improved impact strength, tensile modulus of elasticity, tensile strength, and flexural modulus of elasticity, as compared to previously known composites.
[0035] In some embodiments, the present invention provides the methods including the steps of supplying the cellulose nanofibrils, association of the cellulose nanofibrils with a copolymer of maleic anhydride (MA) to form a mixture of nanofibril-MA copolymer, preparation of the nanofibril-MA copolymer mixture for addition to a matrix polymer, and formation of a composite by associating the nanofibril-MA copolymer mixtures with the matrix polymer, where the amount of cellulose nanofibrils in the composite is between 3% and 50% by weight of the composite. In some embodiments, the preparation step comprises drying the nanofibril-MA copolymer blend. In some embodiments, drying is spray drying. Cellulose Nanofibrils
[0036] In recent years, interest in composites reinforced by renewable materials such as cellulose fibers/wood flour has grown tremendously because of social requests for low environmental stress materials (biodegradable), high durability products, and low maintenance. Cellulose, some of the basic structural components of wood fibers, is the most abundant polymer on earth and has great potential for the preparation of new composite materials with thermoplastic resins. Compared to conventional reinforcements such as glass fibers or inorganic fillers, cellulosic materials offer a number of advantages: lower density (1.5 g/cm3), better recyclability and removal, lower price, reduced abrasion for machinery. processing, and carbon dioxide neutrality.
[0037] Cellulose is a high molecular weight linear syndiotactic homopolymer composed of D-anhydroglycopyranose (AGU) units that are linked together through β-(1^4) glycosidic bonds. The natural affinity for self-adhesion of cellulose chains allows the formation of CNFs with amorphous and crystalline domains. These CNFs can form the basic aggregation units to form microfibrils or cellulose fibers such as pulp fibers. As the bulk wood cell size decreases to nanofibrils, the elastic modulus of cellulose increases from about 10 GPa to 70 GPa or, in some cases, even higher (145 GPa). Compared with stainless steel, the strength-to-weight ratio of cellulose nanocrystals is reported to be eight times greater (see, Ferguson W, Why wood pulp is world's new wonder material, 2012, New Scientist, 2878: 24; see also Cranston et al. , Mechanical testing of thin film nanocellulose materials, 2012, www.tappi.org/Hide/ Events/ 2012-Nanotechnology-Conference/ Papers/12NANO05.aspx, Accessed July 17, 2014).
[0038] In general cellulose nanofibrils, also referred to as nanocellulose, are a material comprising the fine nanosize fibers with a high aspect ratio. Cellulose nanofibrils (CNF) can be prepared in a number of different modes and can exist in a number of different forms, including: (1) bacterial cellulose nanofibers, (2) cellulose nanofibers by means of electrocentrifugation, (3) nanofibrillated cellulose (NFC), and (4) nanorods, cellulose hairs, or cellulose nanocrystals (CNC). In some embodiments, a cellulose nanofibril can be a fiber or particle having a shape in which at least one dimension (eg, diameter, width, thickness, and/or length) is about 100 nanometers or less. In some embodiments, cellulose nanofibrils can have a diameter between 5 and 20 (eg, from about 5 to 15, from about 5 to 10) nanometers inclusive. In some embodiments, the cellulose nanofibrils can be between about 10 and 5,000 in length (for example, from about 10 to 4,000, from about 10 to 3,000, from about 10 to 2,000, from about 10 to 1,000, or from about 10 to 500) nanometers, inclusive.
[0039] In some embodiments, cellulose nanofibrils can be pretreated before association with an MA copolymer. In some embodiments, the pretreatment can be an enzymatic pretreatment, chemical pretreatment, and/or a mechanical pretreatment. In some embodiments, the enzymatic pretreatment is or comprises treatment with a cellulase (e.g., an A-, B-, C-, and/or D-type cellulase). In some embodiments, the chemical pretreatment is or comprises 2, 2, 6, 6-tetramethyl-1-piperidinyloxy (TEMPO) mediated oxidation. In some embodiments, the pretreatment can be or comprise the introduction of the charged group to the nanofibrils (for example, through carboxymethylation). In some embodiments, the pretreatment can be or comprise acetylation of the cellulose nanofibrils.
[0040] According to various modalities, cellulose nanofibrils can be isolated from any cellulosic material. In some embodiments, cellulose nanofibrils are isolated from wood-based material, such as, for example, wood pulp (e.g., bleached Kraft pulp and/or bleached sulfite pulp). In some embodiments, cellulosic nanofibrils can be or comprise wood fibers, paper fibers, pulp fibers, rice husk flour, flax fiber, jute, sisal, microcrystalline cellulose (MCC), nanofibrillated cellulose (NFC) , cellulose nanocrystals (CNCs). Among them, nanofibrillated cellulose and cellulose nanocrystals are generally considered the elemental fibrils of cellulose materials, for example, cellulose nanofibrils (CNFs). Maleic Anhydride Copolymers
[0041] Maleic anhydride (MA) is an organic compound with a chemical formula of C2H2(CO)2O that is employed in a variety of industrial applications, including in the formation of coatings and polymers. Any of a variety of MA copolymers can be employed in various modalities.
[0042] In some embodiments, an MA copolymer is an olefin-MA copolymer. In some embodiments, suitable olefin-MA copolymers are those that provide desirable properties for a particular composite material provided. Non-limiting examples of olefin copolymers that are suitable for use in various embodiments include, but are not limited to, ethylene; alpha olefins such as propylene, 1-butene, 1-pentene, 1-hexene, 1-heptene, 1-octene, 1-nonene, 1-decene and 1-dodecene; 2-butene; 2-pentene; 2-hexene; 2-octene; and combinations of these.
[0043] Among plastic articles, polypropylene (PP) has been widely employed because of its low price, light weight, good wearability, design flexibility, recyclability, and its attractive combination of good processability, mechanical properties, and chemical resistance. Commercially available PP is produced in a wide variety of types with melt flow indices (MFI) ranging from 0.3 to more than 1,000 g / 10 min. Mass production of PP can be easily and economically achieved employing reliable and well-established technologies. For some applications, reinforced by filler or fiber, PP can be used in place of another thermoplastic article and even engineering thermoplastics such as polycarbonate (PC) and acrylonitrile butadiene styrene (ABS). Reinforced PP composites can be produced with many different types of fillers employing various processing techniques including injection molding, compression molding, blow molding, extrusion, and thermoforming. Recent developments in loaded PP composites have shown that high performance materials can be achieved by reinforcing PP using environmentally friendly reinforcements (natural wood fibres/cellulose fibres). In addition, cellulose nanofibrils have also been used to reinforce PP. The addition of CNFs in PP has been observed to improve the mechanical property and thermostability of polypropylene (see Ljungberg et al., New nanocomposite materials reinforced with cellulose whiskers in atactic polypropylene: effect of surface and dispersion characteristics, 2005, Biomacromolecules, 6:2732- 2739; 2005, Biomacromolecules, 6:2732-2739; see also Yang et al., Mechanical properties of cellulose nanofibril-filled polypropylene composites, 2011, Wood Fiber Sci, 43(2):143-152; Bahar et al., Thermal and mechanical properties of polypropylene nanocomposite materials reinforced with nano whiskers, 2012, J Appl Polym Sci, 125(4): 28822889). Thus, in various embodiments, an MA copolymer is MA polypropylene (see Examples below for some such exemplary embodiments).
[0044] In some embodiments, an MA copolymer is an MA polystyrene. Any suitable styrenic monomer can be employed as one or more of the primary monomers according to various modalities. Suitable styrenic monomers include those that provide the desirable properties for one of the specific composite materials provided. Non-limiting examples of suitable styrenic monomers include, but are not limited to styrene, p-methyl styrene, α-methyl styrene, tertiary butyl styrene, dimethyl styrene, their brominated or chlorinated nuclear derivatives and combinations thereof. . associating
[0045] According to various embodiments, associating the cellulose nanofibrils with the MA copolymers can occur in any of a variety of ways. In some embodiments, association occurs under substantially dry conditions. In other words, in some embodiments, at the time of initiation of the association step, equally the cellulose nanofibrils and the MA copolymer are substantially dry (for example, contain less than 1% moisture content based on dry weight in the material oven).
[0046] In some embodiments, the present invention provides the methods of associating cellulose nanofibrils and MA copolymers under non-dry conditions. In some embodiments, at least one of the cellulose nanofibrils or MA copolymers is in solution at the time the association step is initiated. In some embodiments, at least one of the cellulose nanofibrils and MA copolymers comprises a portion of an emulsion at the time the association step is initiated (for example, an MA copolymer is or comprises the dispersed phase of an emulsion) .
[0047] The association step can occur at any of a variety of temperatures. In some embodiments, the association step can take place at a temperature between about 80°C and 220°C (eg, about 80°C and 200°C, about 80°C to 150°C, about 80 °C to 100 °C, about 100 °C to 200 °C), inclusive. In some embodiments, the association step takes place at a temperature at or above 80°C (eg, 90°C, 100°C, 120°C, 140°C, 160°C, 180°C, 200°C , 220°C). In some embodiments, the association step takes place at a temperature at or below 220°C (eg, 200°C, 180°C, 160°C, 140°C, 120°C, 100°C, 90 °C, 80 °C). In some modalities, the temperature remains constant during the association step. In some embodiments, the temperature increases during the association step. In some modalities, the temperature decreases during the association step. In some modalities, the temperature fluctuates during the association step.
[0048] According to various modalities and specific applications, the period of time during which the association step occurs may vary. In some embodiments, the association step is between about 1 minute and 60 minutes in duration (eg, about 5 to 60 minutes, about 5 to 50 minutes, about 5 to 40 minutes, about 5 to 30 minutes , about 5 to 20 minutes, about 5 to 10 minutes). In some embodiments, the association step occurs for at least one minute (for example, at least 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, or 60 minutes). In some modalities, the association step takes place for less than 60 minutes (for example, less than 55, 50, 45, 40, 35, 30, 25, 20, 15, 10, 5, 4, 3, 2 minutes).
[0049] In some modalities, associating refers to the simple mixing of cellulose nanofibrils and MA copolymers in a vessel or container. In some embodiments, associating refers to the simple addition of both the cellulose nanofibrils and the MA copolymer(s) into a vessel of the container (eg, associating occurs through simple diffusion or another passive process). In some arrangements, associating involves active blending. In some embodiments, the active mixture can be or comprise moving, sonicating, or other agitation.
[0050] In some embodiments, the association step comprises combining the cellulose nanofibrils in the suspension with the MA copolymers (eg MAPP) in an emulsion during a spray drying process. In some embodiments, the association step comprises blending the dried cellulose nanofibrils with MA copolymer pellets and a matrix polymer during an extrusion process. Preparing Nanofibril-MA Copolymer Blend for Addition to a Matrix Polymer
[0051] As described herein, including in the Examples below, a variety of methods of preparing a nanofibril-MA copolymer blend for addition to a matrix polymer is considered to be within the scope of the invention. In some embodiments, preparing an AM-nanofibril copolymer blend includes drying the AM-nanofibril copolymer blend. Exemplary, non-limiting methods of drying cellulose nanofibrils include those described in United States Patent 8,372,320, issued February 12, 2013, the description which is incorporated herein by reference in its entirety.
[0052] In some embodiments, the preparation may be or comprise one or more of the following steps: drying the MA-nanofibril copolymer blend, cooling the dry blend of the MA-nanofibril copolymer, and granulating the dry blend of MA-nanofibril copolymer to form a master batch of nanofibril-MA copolymer.
[0053] In some embodiments, drying may be or comprise spray drying. As used herein, the phrase "spray drying" is defined as a processing method for converting a suspension, solution, or emulsion to a solid powder in a single process step. Spray drying involves evaporating moisture from an atomized feed or spray from the suspension by mixing the spray and a drying medium. The drying medium is typically air or nitrogen.
[0054] In some embodiments, cooling may be or comprise the removal of a blend of MAN- nofibril copolymer from a heat source (eg, air-cooling). In some embodiments, cooling can be or comprise active cooling (eg cooling and/or freezing).
[0055] In some embodiments, granulation can be or comprise milling, removing, and/or otherwise converting a mass of material into smaller pieces of material component. In some embodiments, granulation can be or comprise pelletization. As used herein, the term “pelletizing” or “pelletizing” refers to compressing or molding a material into the shape of a pellet. Pellets can be of any size and/or shape suitable for material and/or application.
[0056] In some embodiments, the result of the preparation and/or association step may be or comprise a master batch of dry or substantially dry MA-nanofibril copolymer mixture (for example, as dry or substantially dry pellets, granules and other industrially useful way). Formation of a Composite Material
[0057] The specific method employed to form a specific composite supplied material may vary according to the desired mechanical, flexure, or other properties and may occur by any of the appropriate methods. By way of non-limiting example, two methods are generally used to produce polymer nanocomposites based on different polymer matrices. The first, solution casting, is the method typically employed in solvent-based systems including dispersed aqueous polymers, ie, lattices and organic solvent-based systems. The second method of producing the nanocomposite generally used is the direct composition of polymer fusions and nanoreinforcements. Melt processing is generally considered to be more economical, more flexible to formulate, and involves the composition and manufacturing facilities generally employed in commercial practice. The production of the PP/CNF nanocomposite has been conducted using the fusion process (see Yang and Gardner 2011). However, the present invention provides the methods of directly adding the CNF suspension to polymer melts and forming a composite material with improved/desirable properties. This is surprising, at least in part, because the addition of fillers and/or additives such as nanofibrils ordinarily leads to one of the biggest problems with the formation of composite materials, agglomeration, which complicates the mixing process, and causes serious agglomeration to CNF during the mixing process. Thus, in some embodiments, compounding the CNFs in a dry form with polymer melts through the extrusion process is desirable. The drying of CNFs while maintaining their nanoscale dimensions has been studied in detail and dry forms of CNFs can be produced by, for example, the spray drying method developed by Dr. Gardner's group at University of Maine (see Peng et al., Drying cellulose nanofibrils: in search of a suitable method, 2012, Cellulose, 19(1): 91-102; Cellulose, 19(1): 91-102; see also Peng et al., Spray-drying cellulose nanofibrils: effect of drying process parameters on particle morphology and size distribution, 2012, Wood and Fiber Sci, 44(4): 1-14).
[0058] In addition to the agglomeration problems, another significant challenge in the development of CNF-reinforced PP nanocomposites is associated with the surface properties of dry CNFs. The incompatibility between hydrophilic cellulose fibers and hydrophilic polypropylene has been observed to seriously degrade the mechanical properties of the composites and is thought to be due, at least in part, to the high density of hydroxyl groups on the surface of the CNFs. Furthermore, hydrogen bonds between the hydroxyl groups allow for unwanted adhesion between the cellulose fibers. At the nanoscale dimensions, cellulose fibrils can easily interact and clump together when in close proximity to each other.
[0059] To avoid these inconveniences, in some modalities, cellulose fiber can be subjected to specific surface modifications to: 1) decrease agglomeration, 2) provide an efficient hydrophilic barrier, and 3) minimize its interfacial energy with the matrix of non-polar polymer and thus generate optimal adhesion. Furthermore, the improvement in this interfacial strength, which is a basic requirement for the mechanical performance of some modalities, is achieved by chain entanglement between matrix macromolecules and long chains attached to the fiber surface or, in some modalities, by the establishment of a continuity of covalent bonds at the interface between the two components of the composite. The chemical moieties of cellulose exploited for this purpose are its hydroxyl functional groups, which have a source of well-known reactions employed to prepare a wide range of cellulose derivatives, including esters, ethers, etc. According to various embodiments, such modifications are limited to the OH-surface groups to preserve the integrity of the fibers and thus their mechanical strength.
[0060] Physical treatments and chemical modifications were employed to treat the surface of cellulose fibers with the specific purpose of their subsequent incorporation into polymer matrices. Reported methods of physical treatment include plasma, corona, laser, vacuum ultraviolet, and Y-ray treatments (see Belgacem and Gandini, The Surface Modification of Cellulose Fibers for Use as Reinforcing Elements in Composite Material, 2005, Composite Interfaces, 12(1-2): 41-75). Chemical treatments employing coupling agents are generally employed to alter the nature of the surface of the cellulose, in which a compound (coupling agent) is employed to treat the substrate formation of a bridge of chemical bonds between the fiber and the matrix. In general, coupling agents facilitate optimal stress transfer at the fiber-matrix interface. Various chemical treatments have been reported on the cellulose surface, such as silane treatment, esterification, alkali treatment, treatment with polypropylene grafted on maleic anhydride (MAPP), and others. In some embodiments, coupling agent treatment employing maleic anhydride grafted polypropylene (MAPP) has been found to be most effective in improving the mechanical properties of cellulose composite materials (see Examples below). Improved Properties
[0061] As described here, the methods provided allow for the production of composite materials with the improved properties. In some embodiments, a composite provided is characterized as having an impact strength that is greater than that of a composite consisting of only the matrix polymer and cellulose nanofibrils. In some embodiments, the compositions provided are characterized as having an impact strength of at least 5% (eg 6%, 7%, 8%, 9%, 10%, 15%, 20%, 25%, 30% , 35%, 40%, 45%, or 50%) greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils.
[0062] In some embodiments, a supplied composite is characterized as having a tensile modulus of elasticity that is greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the compositions are characterized as having a tensile modulus of elasticity of at least 5% (eg, 6%, 7%, 8%, 9%, 10%, 15%, 20%, 25%, 30 %, 35%, 40%, 45%, or 50%) greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the composite materials provided may exhibit the increased tensile modulus of elasticity as compared to a composite consisting of only the matrix polymer and cellulose nanofibrils while maintaining an impact strength level at or above the impact resistance presented by the composite consisting of only the matrix polymer and the cellulose nanofibrils.
[0063] In some embodiments, a composite provided is characterized as having a tensile strength that is greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the compositions are characterized as having a tensile strength of at least 5% (eg, 6%, 7%, 8%, 9%, 10%, 15%, 20%, 25%, 30%, 35%, 40%, 45%, or 50%) greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the composite materials provided may exhibit increased tensile strength as compared to a composite consisting of only the matrix polymer and cellulose nanofibrils while maintaining an impact strength level at or above impact strength presented by the composite consisting of only the matrix polymer and the cellulose nanofibrils.
[0064] In some embodiments, a composite provided is characterized as having a flexural modulus of elasticity that is greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the compositions are characterized as having a flexural modulus of elasticity of at least 5% (eg, 6%, 7%, 8%, 9%, 10%, 15%, 20%, 25%, 30% , 35%, 40%, 45%, or 50%) greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the composite materials provided may exhibit increased flexural modulus of elasticity when compared to a composite consisting of only the matrix polymer and cellulose nanofibrils while maintaining a level of impact strength in or above the impact resistance presented by the composite consisting of only the matrix polymer and the cellulose nanofibrils.
[0065] In some embodiments, a composite provided is characterized as having a flexural strength that is greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the compositions are characterized as having a flexural strength of at least 5% (eg, 6%, 7%, 8%, 9%, 10%, 15%, 20%, 25%, 30%, 35% , 40%, 45%, or 50%) greater than that of a composite consisting of only the matrix polymer and the cellulose nanofibrils. In some embodiments, the composite materials provided may exhibit increased flexural strength as compared to a composite consisting of only the matrix polymer and cellulose nanofibrils while maintaining an impact strength level at or above the reported impact strength by the composite consisting of only the matrix polymer and the cellulose nanofibrils.ExamplesExample 1
[0066] This Example shows, among other things, that the compositions and methods provided are capable of achieving reinforced polypropylene nanocomposite materials with surprisingly advantageous properties.
[0067] Unless otherwise specified, the processes employed in this Example were as follows: Materials
[0068] The polypropylene (PP) employed as the thermoplastic matrix polymer in this Example was supplied by INEOS Olefins & Polymers USA (League City, Texas) and is marketed under the trade name of polypropylene homopolymer H05A-00. The density of the PP matrix was 0.89 - 0.93 g/cm3. The melt flow index for this material was 4.70 g/10 min at the temperature of 230°C at the 2.16 kg charge.
[0069] A 3% by weight cellulose nanofibril suspension supplied by the Chemical Engineering Department at the University of Maine was employed as the raw material. The CNF suspension was stored in a plastic container at room temperature before drying.
Nonionic polypropylene emulsion coupling agents (FGLASS™ X35 MAPP emulsion) and maleic anhydride (MAPP) modified polypropylene homopolymer pellets (Polybond 3200) were supplied by Michelman, Inc. (Cincinnati). , Ohio) and Chemtura Corporation (Lawrenceville, Georgia). In the polypropylene emulsion (FGLASS™ X35), the non-volatile conductor was polypropylene maleate with a solids content of 34 to 36 % by weight. The specific gravity for the emulsion was from 0.96 to 0.98 g/cm3. At 22°C, the Brookfield viscosity of the emulsion with stem number 2 rotating at 60 RPM was about 200 cps. The level of maleic anhydride in Polybond 3200 pellets was about 1.0% by weight. The melting point and density of Polybond 3200 was 157°C and 0.91 g/cm 3 . The melt flow at 190°C with a load of 2.16 kg was 115 g/10 minutes. Experimental Design and Sample Preparation
[0071] A thermal composition process was employed for the production of PP nanocomposites reinforced by CNFs. The composite formulations are shown in Table 1. The CNFs in dry form were obtained through a first spray drying process. And then, the concept of “master batch” was used to disperse the CNFs in the polymer matrix (PP or MAPP). The “master batch” is typically used in the field of plastic composition for coloring plastics or imparting other properties to plastics. In this Example, the master batch including CNFs, MAPP, and/or PP was produced first and then the ground pellets from the master batch were redispersed in the PP die employing the extrusion process to produce the composites. Table 1. Formulation of Composites ( % by weight)

[0072] To generate the master batches for each sample shown in Table 1, the weight ratio of CNFs to polymers (PP or PP plus MAPP) was maintained at 81 to 200. Based on the two different treatments with coupling agent, two different processes were designed to generate the master batch and composites (Figure 1). In process I, the CNF suspension was dried first and then the dried CNFs were mixed with the PP or PP pellets plus MAPP pellets to produce the PP + CNF and PP + MAPP + CNF master batches. The final corresponding composites were produced employing an extrusion process with the formulations shown in Table 1. For the CNFs treated with MAPP emulsion, process II in FIGURE 1 was employed. The suspension of CNF treated with MAPP emulsion was dried and then the dry mixture of CNFs and MAPP was compounded with PP to generate the master batch of PP + CNF_MAPP. The final composite was produced using the same extrusion process. Pure PP and PP blends and 2% by weight MAPP pellets were also processed using the same extrusion procedures.
[0073] The drying of the CNF suspension (treated and untreated with MAPP emulsion) was conducted through a laboratory scale spray dryer from Buchi B-290 (Buchi, Switzerland). The spray drying process was carried out as previously described (see together Peng et al., 2012, referenced above). In this Example, the 1% by weight CNF suspension was dried at the inlet temperature of 200°C, spray gas flow of 601 l/h, pump rate of 48 ml/min, and gas flow rate of drying of approximately 35 m3/h. For the treatment of the emulsion in the CNF suspension, the MAPP emulsion was first added to the CNF suspension at 1% by weight with the CNF to MAPP weight ratio of 3:1 and then mixed using a Speed Mixer® (Flack Tek Inc., US) for 2 minutes at 2000 rpm, followed by ultrasonic treatment at 80°C for 1 hour. The treated suspension was then dried using the same spray drying process.
[0074] A thermal compounding process employed to produce the master batch materials, and was performed in a CW Brabender Prep Mixer® (CW Brabender Instruments, INC., South Hackensack, NJ) by controlling the mixing bowl temperature which has a capacity of 200 grams. Polymer pellets (PP or PP plus MAPP) were initially melted at 200°C and then compounded with the corresponding weight of the CNFs or CNFs treated at Brabender for about 8 to 10 minutes at 200°C with the bowl for mixing by rotating at the speed of 60 rpm, followed by milling. Prior to composition, PP pellets, MAPP pellets, CNFs (treated and untreated) were dried in an oven at 105 °C for 2 hours. The ground pellets from the master batch were mixed with the PP pellets and then extruded at 60 rpm through a 20 mm CW Brabender of Clamshell Segmented Twin Screw Extruder joined to the Intelli-Torque Plastic-Corder (CW Brabender) drive system Instruments, INC., South Hackensack, NJ). Pellets were fed into the first zone of the extruder through the feed tank at about 70 g/min. The system screw configuration was Stand-alone TSE20/40D. The five heating zones were all activated at 200°C. The extruded composite was passed through a die of two nozzles with the diameter of each nozzle being 2.7 mm. The matrix temperature was also maintained at 200°C. The extrudate, in its molten state, was cooled and solidified directly in an air-cooling system while being extracted with a DORNER MFG Series 2200 End Drive Conveyor. Corp. (Hartland, WI). And then the extruded solidified was pelletized through a pelletizer designed for laboratory extrusion activated from CW Brabender Instruments, INC. The pelletized composite material was then injection molded into the shapes specified in ASTM D638 and D790 for tensile, flexural impact testing and Izod. A Model #50 “Minijector” injection molder with a ram pressure of 2500 psi at 200°C was employed to produce the samples. The molded samples were held in the mold for 10 seconds to cool. The samples were then placed in plastic containers and stored in desiccators to maintain dryness. Particle Size Analysis
[0075] The particle size distributions of the CNFs were determined using a Mastersizer 2000 particle size analyzer (Malvern Instruments, Malvern, UK), for analysis of dry samples using the Sirocco 2000 dry dispersion unit and for analysis of samples from suspension employing the Hydro 2000S unit. The operating principle of this equipment is based on the laser diffraction technique, which takes advantage of the phenomenon with the proviso that the particles scatter light in all directions with an angular intensity pattern that is dependent on the particle size. Larger particles should scatter at small angles and smaller particles scatter at wide angles. With intensity pattern detection, particle size can be determined using Mie theory (Mie 1908). For the characterization of the dry CNFs, the material under investigation was first placed on the vibrating tray of the Sirocco dry dispersion unit. A stable sample flow in the dispersion system and an optimal sample concentration through the measuring cell must then be achieved by adjusting the air pressure and feed rate. In this study, all measurements were taken at 4 bar air pressure and 20% feeder capacity. For the analysis of the particle size distribution of the CNFs in the suspension, a small amount of the CNF suspension (treated and untreated) was prepared using the Speed Mixer and added to the dispersion cell and then pumped into the measurement zone . The agitation produced by the pump and the sonication applied can be useful to maintain a stable dispersion of the CNFs in water. The pump rate and sonication employed in this study is 2,100 rpm and 20% of the sonication capacity. Five replications were performed for each sample. Mean particle size distributions were reported. Fusion Flow Index
[0076] The melt flux index (MFI), as used herein, is defined as the mass of a polymer melt in grams extruded in ten minutes through a standard capillary of a specific length and diameter in an ad flow indexer. fusion with a fixed pressure is applied to the fusion at a prescribed temperature as specified by ASTM D1238-10. The melt flow index of all composite samples was measured using the Dynisco Melt Flow Indexer Model 4004 (Morgantown, PA). The standard die employed within the Dynisco Melt Flow Indexer barrel had an orifice diameter of 2,095 mm and length of 8 mm. The instrument was first heated to the test temperature of 230°C and held for at least 15 minutes before loading the composite samples. A measured amount of the material (ranging from 3 to 5 g) in pellet form after extrusion was loaded into the barrel and conditioned. The piston was then inserted into the barrel and the test weight of 2.16 kg was added to the top of the piston after a 2 minute “melting” period, starting the extrusion. The extruded cut time interval was enabled as one minute per ASTM D 1238 for composite samples. Cutting of the extrudates was completed manually. Extrudes were discarded if there were visible bubbles. Five extrudates were collected for each sample and weighed at approximately 1 mg. The mean value was calculated and then converted to the melt flow rate standard number with units of g/10 minutes. The tests were considered valid if the difference between the average and maximum and minimum values was not greater than 15% of the average value. Traction Test
[0077] Tensile tests were performed to examine the static tensile strength and modulus of elasticity (MOE) of the composite samples according to ASTM D638-10 standard and under a displacement control load with load speed at five mm/min (nominal strain rate at start of test = 0.1 min-1). An extensometer was used to determine the elongation of the samples. Tests were performed at an environmentally conditioned temperature at 23 ± 2 °C and 50 ± 5% RH. A 10,000-N load cell coupled to a hydraulic servo testing machine (Instron 5966) was employed to collect the stress deformation data. At least five samples were tested for each sample and then the mean standard deviation was calculated. Flexural Test
[0078] Flexural tests were performed to examine the 3 static points bending strength and modulus of elasticity of the composite samples according to ASTM standard D790-10 and under a load displacement control (load ratio = 1.27 mm / min). The strain rate of the outer fiber is 0.01 min-1. Tests were performed in an environmentally conditioned location at 23 ± 2°C and 50 ± 5% RH. The ranges applied were 50.8 mm in length for a length/depth ratio of 16. A 266.9-N load cell attached to the hydraulic servo testing machine (Instron 8872) was employed to collect the stress deformation data. Static flexural loads were applied for five replications for each sample and then the mean standard deviation was calculated. Izod Impact Test
[0079] The izod impact tests were performed on the composite samples according to ASTM D256-10 employing a Ceast pendulum impact tester (Resil Model 50B). The notch was produced on the impact samples using a Ceast notch cutting machine. Tests were performed in a conditioned room at 23 ± 2 °C and 50 ± 5% RH. The test was applied to 10 replicates for each sample. The mean value of impact strength in kJ / m2 and standard deviation were reported. Scanning Electron Microscopy
[0080] The morphologies of spray-dried CNFs and fractured composite samples were directly studied by SEM using the Hitachi Tabletop SEM TM 3000 microscope (Hitachi High- Technologies Corporation, Tokyo, Japan) at an accelerating voltage of 15 kV. Micrographs at various magnifications were obtained.
[0081] The particle size distributions of suspended CNFs (grey lines) measured by laser diffraction are shown in FIGURE 2. In laser diffraction, the diameters of spherical materials that generate the same intensity patterns as the measured samples are characterized as the particle sizes of the materials concerned (equivalent spherical diameter). Particle size distribution results obtained by laser diffraction are reported on a volume basis. A single peak with particle size from 0.6 µM to 2000 was observed by CNF in suspension (CNF_1 in FIGURE 2). After about 843.4 mm, there is only about 0.1% by volume of the CNFs in suspension which is not observable in the particle size distribution curve depicted in Figure 2. The pattern of percentile readings D (N, 0.1), D (N, 0.5) and D (N, 0.9) particle sizes from the distribution statistics are 8.9, 43.4, and 151.6 µM, e. 50% of volume, in CNFs per suspension is less than 43.4 µm. Adding MAPP emulsion with solids content (maleated polypropylene) particle sizes from 1.5 to 84.3 µM (MAPP in FIGURE 2) in the CNF suspension changed the particle size distribution of the CNFs. After the mixing process with a speed mixer, a second peak of about 7.7% by volume of particles with sizes from about 266.7 to 843.4 µM was observed in the particle size distribution curve (CNF_2 in Figure2). With ultrasonic treatment at 80°C for one hour, the particle size distribution of treated CNFs (CNF_3) in suspension changed again. The second peak observed before the ultrasonic treatment shifts to a larger size area ranging from 355.7 to 2000 um. The volume of particles in this size range also increased to about 19.4%. The larger size of CNFs detected during laser diffraction measurement after MAPP emulsion treatment may indicate that grafting of MAPP to CNFs occurred during the mixing process and ultrasound treatment at 80 °C promoted the reaction between MAPP and CNFs . In the study by Qiu et al. (Interfacial interactions of a novel mechanochemical compound of cellulose with maleated polypropylene, 2004, J. Appl Polym Sci, 94: 1326-1335), the formation of ester bonds between cellulose and MAPP was observed during ball milling of crystalline cellulose and MAPP. Without intending to be held to a particular theory, another important possible contribution to the larger size of CNFs may be related to the bridges built between CNFs by MAPP molecules, resulting in CNFs bound in the above or double particle sizes. The formation of the CNFs bond is similar to the process of formation of micelles in suspension. Polypropylene part in MAPP molecules form the core with the CNFS parts as the tails in contact with the surrounding water. The decrease in the proportion of particles in smaller sizes seems to validate this theory.
[0082] After spray drying, the dry particle size distributions of CNFs (CNF in Figure 2) characterized using the same technique are shown as black lines in Figure 2. The particle sizes of dry CNFs ranged between 0.1 and 266.7 µM with standard readings of percentiles D (N, 0.1), D (N, 0.5) and D (N, 0.9) of 2.4, 10.0, and 55, 4 mm, respectively. Compared to suspended CNFs, the particle sizes of dry CNFs are significantly smaller and the distribution is narrower. Larger size exclusion of CNFs from suspension was observed in the spray drying process. A batch of CNFs were deposited on the wall of the drying chamber. The smallest of the particles decreased from 0.6 µm in suspension to 0.1 µM in dry form. The drying process can bend the softest CNFs in suspension, forming smaller or different shaped particles that generate smaller size in laser diffraction measurement. With the same drying process, the CNFs treated with MAPP emulsion (MAPP CNF in FIGURE 2) after drying showed similar particle size distribution with untouched CNFs except for the larger relatively large particle size proportion ranging from 84.3 to 266.7 µM. As a result, the default percentile readings for D (N, 0.1) and D (N, 0.5) are slightly higher than that of the pristine CNFs with values of 2.7 and 11.1 AM while the value of D (N, 0.9) change to a greater number of 84.8 µM. The differences of the three readings demonstrate the treatment effect of MAPP emulsions. During the drying process, larger particles from the treated CNFs that were possibly caused by engraftment of MAPP molecules were eliminated, resulting in the possibility of lower MAPP content in the dried CNFs than the designed value.
[0083] The SEM micrograms of the dry CNFs are shown in FIGURE 3. Several different particle morphologies are observed: fibrous materials with different diameters and lengths, similar to tapes (platelets) or materials with different thickness, width or length, and the irregular shape of materials with different degrees of agglomeration. Detailed information on the formation of spray-dried CNFs morphology can be found in a previous article (see Peng et al. 2012). Fibrous CNF diameters range from about 0.1 to several µm, with length up to about 500 µm. Tape-like materials are usually several µm wide, submicron meters thick, and tens of micron meters long. These two types of CNFs are usually formed during the CNF manufacturing process. After spray drying, they almost inherited their original shape and dimensions. Agglomerated particles are mainly formed during the spray drying process with the smallest size and CNFs vary in a range of sizes and shapes. The particle size distribution of CNFs characterized by laser diffraction showed the equivalent spherical diameters which is good for comparison between different samples. For real particle sizes, characterization combining these two techniques gives more reasonable results. SEM micrograms of spray-dried CNFs treated using MAPP emulsion (not shown) showed similar morphologies with pristine CNFs. The observed difference in the particle size distribution of FIGURE 2 between treated and untreated CNFs cannot be detected in the SEM micrograms. Fusion Flow Index
[0084] The melt flow indices of all composites were measured in accordance with ASTM D1238-10 with a. The melt flow index data and standard deviations are shown in Table 2. The melt melt index (MFI) is a measure of flow inversely related to melt viscosity. MFI measurement is a simple but very useful method to estimate the chain mobility of polymer composites. As can be seen from Table 2, the melt index of PP flux after the extrusion process is 7.2 g / 10 min. After the addition of 2 wt% MAPP, the MFI of the mixture increased to 9.3 g / 10 min, which is expected to add lower viscosity of MAPP to the sediment. With the addition of 6 wt% Spray-dried CNFs in PP, the blend showed a higher IMF (lower viscosity) compared to PP. Generally, the addition of natural fibers to polymer composites is known to restrict molecular motion in the matrix and cause the reduction of MFI values (see Jam and Behravesh, The Flow Behavior of HDPE-thin Wood Particle Composites, 2007, J. Thermoplastic Composite Materials, 20(5): 439-451; see also Shumigin et al, Rheological and Mechanical Properties of Poly(lactic acid)/cellulose composites, 2011, Materials Sci, 17(1): 32-37). .. However, an increase in the MFI value was observed in this example, which may indicate a better molecular movement between polymer chains in the PP/CNFs system. Without intending to be held to a particular theory, one of the possibilities is the low level of load of CNFs used in the study. Second, a phase separation between PP and CNFs can be formed during the mixing process using an extruder, due to the incompatibility between hydrophilic and hydrophobic PP CNFs. At the same time, the small size of CNFs (high surface area) can form a significant amount of separate surfaces. Air can be trapped in the space between CNFs and PP, facilitating the movement of polymer molecules and CNFs. The high measuring temperature of 230°C and the melt retention time (2 minutes) inside the melt flow indexing drum can also contribute to the formation of volatiles and between CNFs PP due to decomposition or dehydration of CNFs. Furthermore, the separation of PP molecules by CNFs decreased the entanglement density of PP molecules, resulting in a higher MFI value. Use of MAPP in the PP/CNFs system decreased the MFI value (Table 2). Cross-linking between CNFs and PP can be established, reducing the amount of separation surfaces. Simultaneously, harder CNFs limit the movement of PP molecules, lowering MFI values. The modification in the PP/CNFs system using MAPP pellets showed slightly lower IFM compared to the PP reinforced by MAPP emulsion treated CNFs, indicating that the MAPP sediment treatment is more efficient in building the bonds between CNFs and PP than the treatment MAPP emulsion in this study. Table 2. The melt flow index and the tensile deformation at maximum load
a - The letter A, B, and C represent the significant levels in the statistical analysis. Values with different letters are significantly different from each other (ie, the group with "A" is significantly different from the groups with "B", "C" and "D"). Mechanical Properties and Morphologies of Surface Fracture
[0085] Tensile tests on all composites were conducted in accordance with ASTM D 638-10. Tensile test results for all compounds are shown in FIGURE 4 and Table 3, including elastic modulus of elasticity (MOE) and tensile strength. Statistical analyzes on the tensile MOE and tensile strength of the different composites were performed at a significance level of 0.05. The results are shown in Table 3 with the supports. Values with different letters (A, B, C, and D) are significantly different from each other (ie, "A" is statistically different from "B", "C" and "D", etc). PP had an MOE tensile and tensile strength of 1.43 GPa and 29.5 MPa, which are the lowest values among all composites. According to the tensile load, PP sample reacted with an initial elastic deformation, quickly followed by a viscoelastic part, where the tension gradually increased until reaching a maximum at a yield point. After the yield point, continued deformation resulted in neck narrowing and propagation along the length of the sample. Decreasing the tension towards a threshold value with the occurrence of cold stretching until the sample failed.
[0086] The MOE tensile of PP was calculated using the elastic behavior during the tensile test while the tensile strength was derived from the yield point. Addition of two weight percent MAPP pellets to PP did not change the tensile behavior of PP. The obtained MOE tensile and tensile strength are not significantly different from pure PP (Table 3 and Figure 4). The tensile deformation processes observed in PP reinforced CNFs were different from pure PP. All samples failed with less tension effort compared to pure PP. Stress strains at the maximum load of all compounds are also reduced. Data measured during the tensile test are shown in Table 2. Statistical analysis on strain strains at maximum load for all compounds is conducted at a significance level of 0.05. As can be seen in Table 2, the addition of 2% by weight of MAPP in PP did not change the tensile stress (9.2%) at maximum load, while the addition of CNFs (treated and untreated) significantly decreased the tension effort at full load. With the addition of CNFs in PP in 6 weight. %, The tensile strength MOE and tensile strength of the composite are increased to 1.71 GPa and 30.4 MPa, which corresponds to about 20% improvement in MOE and 3% compared to the strength of pure PP. At the same time, the tension effort at full load decreased from 9.2% to 6.4%, indicating more fragile failure of PP + PP than CNF. The addition of MAPP-treated CNFs (or emulsion or sediment) to pure PP resulted in composites with even higher MOE tensile strength and tensile strength (Table 3).
[0087] The MOE tensile (1.96 GPa) of CNF reinforced PP treated with MAPP emulsion (PP + MAPP_CNF) is about 37% higher than that of pure PP (1.43 GPa) and composite produced by addition of MAPP pellets for the PP / CNFs system (PP + MAPP + CNF) presented about 36 % higher than the MOE (1.94 GPa) traction of the PP. Simultaneously, the tensile stress at maximum load decreased from 9.2% for PP to 6.1% and 6.7% for PP + PP + MAPP_CNF and MAPP + CNF, respectively. Tensile MOE is related to the ratio between tension and tension in the elastic phase of a tensile test. The tensile MOE of reinforced composites is generally determined by the elastic properties of their components. With the addition of harder CNFs in PP, the composite modulus can be easily improved. At the molecular level, the movement of molecules in PP reinforced composite PP CNFs was constrained by CNFs, resulting in greater stress in the elastic phase of the tensile test compared to stress in pure PP. Interestingly, the addition of MAPP in the composite of pristine reinforced PP CNFs, which was used to increase the interfacial adhesion between CNFs and PP, significantly improved the MOE tensile strength. This phenomenon is rarely observed in reinforced polymer composites (see Fu and other Effects of Particle Size, Particle/Matrix Interface, Adhesion and Particle Loading on the Mechanical Properties of Polymer Particle Composites, 2008, Composites: Part B, 39 :933-961). The tensile MOE is measured in the area of elastic deformation, with a small amount of stress. There was insufficient deformation to cause the separation of the interface in the elastic domain. Increased interfacial bonding may not be able to improve MOE traction. Therefore, and without intending to be held to a particular theory, for the MAPP-enhanced PP emulsion treated CNFs, the higher tensile MOE could be caused by: (1) the higher content of CNFs in the spray dried sample of MAPP_CNF and/or (2) the different particle size distribution of MAPP treated CNFs and pristine CNFs.
[0088] In the spray dried MAPP_CNF example, the MAPP content could be less than the designed value while the CNFs content could be higher, resulting in the higher weight percentage of CNFs in the final composites. The modulus of reinforced composites consistently increases with increasing reinforcement content. The addition of MAPP pellets in the PP/CNFs system increased the compatibility between CNFs and PP, facilitating the uniform dispersion of the CNFs in PP. As a result, the MOE tensile strength was improved. Alternatively or additionally, the improved tensile MOE could also be associated with the crystal structure of the compound. In relation to the tensile strength, of PP reinforced by MAPP sediment treated CNFs (32.8 MPa), it is about 11% higher than that of pure PP (29.5 MPa). With the reinforcement of MAPP emulsion treated CNFs, the tensile strength of PP increased to 31.2 MPa, which is about 6% higher than that of pure PP (Table 3). As used herein, composite tensile strength is defined as the yield stress the composite can sustain under uniaxial tensile load. The yield point is considered to be associated with the appearance of significant plastic flow. On a molecular level, yield behavior is associated with inter-chain running, segmental-chain motion, and chain-reforming.
[0089] With the introduction of dura CNFs in PP, the mobility and deformation of the matrix are immobilized by mechanical means. These mechanical constraints can partially increase the voltage transformation between PP and CNF molecules, especially in high aspect ratio reinforcements. Furthermore, the thin and long fibrous CNFs shown in FIGURE 3 can entangle with PP molecules, contributing to improved strength. However, the effect of mechanical restraint is limited. As a result, the tensile strength of pristine CNFs reinforced PP was increased only by three percentages compared to pure PP. After MAPP treatment, the tensile strength of composites was 6 or 11% higher than PP. When the MAPP coupling agent is introduced, the compatibility between the PP and CNFs has been increased and neighboring polymer chains CNFs can bond to the filler surface and form a layer of immobilized polymer chains. Thus, the yield increase compared to untreated CNFs stress as a result of improved compatibility. These observations are consistent with the melt flow index data. With MAPP treatment, lower MFI (higher viscosity) were obtained for treated animals CNFs reinforced composite PP (Table 2). It has been suggested that the mobility of PP macromolecules is much more restricted, as a result of the stronger interaction between polymer and treated CNFs than in pristine PP-enhanced CNFs. Characterization of composite fracture surfaces using SEM further demonstrate this theory, which is discussed in the following section. Table 3. Mechanical properties of Composites
a = Modulus of elasticity; b = standard deviation; C = The letter A, B, C, and D represent the significant levels in the statistical analysis. Values with different letters are significantly different another way as described for Table 2.
[0090] The deformation and microstructure evolution of semi-crystalline PP under tensile load has been intensively studied. In this study, the sample surface after stretching was directly characterized using Hitachi Tabletop Microscope SEM TM 3000. The SEM micrograms of PP and PP + MAPP are shown in FIGURE 5. The addition of MAPP pellets in PP did not appear to change the PP fracture morphology. Under tension, the spherulitic texture of PP is deformed. During the sample stretching phase (after originating), the initial PP spherulitic structure converts to an oriented and elongated structure, as shown in FIGURE 5A. At the same time, the plastic deformation (slide chain) on the top surface forms a fibrous structure oriented at an angle of about 45 degrees with respect to the tension direction.
[0091] According to the theory of Dijkstra et al. (A study of transition microscopy of yielding to cracking in polypropylene 2002, Polymer Engineering and Sci, 42 (1): 152-160), the direction at 45 degrees to the Traction shaft is the main direction of shear tension, that is, the ideal position for PP chain slip. Crack-induced PP outer layer failure, which was initiated by cracking, was also seen in FIGURE 5A. The initial craze formed at the yield point of the tensile test propagates through the cross-section with the fibrous structures formed in the axis of stretching to the tension. Micro-voids are generated because of fragmentation and division of the stretched fibrils. With further increase in tensile stress, coalescence of larger micro-void spaces forms null or break, resulting in failure of the outer layer of PP shown in FIGURE 5A. Beautiful cracks and tear bands along the axis of pull can also be seen after the failure of the outer layer in FIGURE 5A. Additional bleaching stress occurred at the same time that cracking began and also in the stretching phase during the tensile test.
[0092] The cross sections of the broken samples after the tensile test were also examined using SEM (Figure 5B). Four different fracture morphologies are seen in FIGURE 5B: region 1, crazing-tearing; region 2, with fragile ductile fracture pulling fibrils / microfibrils; region 3, atrial (disentanglement); and in region 4, splitting. The morphology of region 1 of FIGURE 5B is similar to the fracture morphology formed in FIGURE 5A, which is defined as crack-tear in the study by Dasari et al. (2003). The greatest increase in crack-tear fracture morphology is shown in FIGURE 5C. As the tensile stress continues to increase, more and more voids are created as the crack slips and bands tear, resulting in brittle failure, as shown in region 2 of FIGURE 5B. The highest magnification WITHOUT micrograms of region 2 in FIGURE 5B is shown in Figure 5D. Although the region appears to be fragile, PP partial atrial was observed. Uninterrupted fibrils continued to plastically deform as fibril disentanglement occurred. Region 2 is the transition phase from the crazing-tearing of region 1 the fibrillation occurred in region 3 of FIGURE 5B. High atrial density of stretched crack bands is observed in region 3. According to the tensile load with decreasing cross-sectional area, continuing skidding of the fibrillar structures resulted in cracks disentangling at high tensile stress, forming the morphology atrial. As fibrillation grows inward, the central part of the sample cannot maintain the tensile stress. The fragile fracture with split current occurred in region 4 of FIGURE 5B. The highest magnification SEM micrograms of regions 3 and 4 are shown in Figs. 5E and F.
[0093] The fracture surface morphologies of CNFs (treated and untreated) reinforced PP are shown in FIGURE 6. As shown in FIGURE 6, the addition of PP to CNFs completely changed the fracture morphologies. Only one type of fracture surface morphology was observed. All fracture surfaces of the composites become rough compared to pure PP (FIGURE 6A). In composites, PP and CNFs composite a heterogeneous system with different resistance capacity to the applied force. According to the uniaxial tensile load, non-coherent movements between PP and CNFs occurred and cause detachment between PP and CNFs, forming the fibrillation fracture morphology as shown in FIGURE 6B. At the same time, CNFs well dispersed in PP can be observed. The highest magnification micrograms of SEM of CNFs in PP are shown in Figs. 6C, D, E and F. Figure 6C shows no binding between CNFs and PP in the pristine sample CNFs reinforced PP (PP + CNF), while FIGURE 6E and F indicates strong interactions between CNFs and the polymer matrix in the PP sample + MAPP + CNF. Thus, a significantly higher tensile strength (32.8 MPa) was obtained for PP + MAPP + CNF compared to PP + CNF (30.4 MPa).
[0094] For the sample of PP + MAPP_CNFs, the tensile strength located between PP + PP + CNF and MAPP + CNF (Table 3). Examination of the fracture surface of PP + MAPP_CNF shows no interaction between CNFs and polymer matrix (FIGURE 6D), a case similar to pristine reinforced PP CNFs. However, the tensile strength of MAPP reinforced PP by emulsion treated CNFs is higher than that of pristine PP reinforced CNFs. One explanation is that the MAPP emulsion treatment worked but is not as effective as the MAPP sediment treatment. During spray drying of the MAPP emulsion treated CNFs, the MAPP molecules can be buried inside the CNF agglomerates, avoiding contact with the PP in the extrusion process. The possibility to exclude MAPP during the spray drying process can contribute to the different mechanical properties, too. Different granulometrics can also provide another explanation. Therefore, the treatment process in MAPP CNFs emulsion has to be optimised. At the same time, PP reinforced with MAPP emulsion treated CNFs showed lower tensile stress (6.1%) at maximum load compared to PP reinforced with CNFs (6.4%) and MAPP sediment treated CNFs (6.7%) . MAPP emulsion treatment in CNFs resulted in a greater proportion of large relative particle size (84.3-266.7 M) after spray drying compared to spray-dried pristine CNFs. The relatively larger proportion of large particle can cause the least tensile deformation at maximum load for PP reinforced by MAPP emulsion treated CNFs.
[0095] The bending properties of all composites are tested in accordance with ASTM D 790-10 and the data are shown in Table 3 and FIGURE 7. During bending testing, all composites did not yield or break within the limit of tension 5%. The strength data shown in Table 3 and Figure 7 are calculated based on the 5% strain limit. The lowest MOE flexure and flexural strength is pure PP with values of 1.35 GPa and 46.9 MPa. All other compounds with added MAPP and/or CNFs showed a significant improvement over flexural MOE and flexural strength (Table 3). The addition of 2 wt% MAPP pellets in PP increased the MOE flexion and strength to 1.46 GPa and 50.5 MPa, which corresponds to about an eight percent improvement in both MOE and strength. Adding CNFs in pure PP significantly improves flexural MOE at 1.60 GPa while flexural strength is not significantly different. MAPP treatment in CNFs did not appear to change MOE flexion or strength significantly (Table 3). The highest bending modulus of elasticity and flexural strength are 1.63 GPa and 52.4 MPa, which represents about 21% improvement and 12%. Bending behaviors of composites are slightly different from tensile performance. The bending properties is a composite characteristic of tensile and compression. In addition, the bending test was performed with an outer fiber strain rate of 0.01 min-1, while the initial outer fiber strain rate of tensile test is 0.1 min-1. The mechanical properties and fracture surface morphologies of homopolymeric polypropylenes and their filled compounds are appreciably influenced by the strain rate.
[0096] The Izod impact property with notching for all compounds described in this example were measured according to ASTM D 256-10. Impact strength data are shown in Table 3 and Figure 8. Statistical analysis was performed on impact strength at a significance level of 0.05. The impact strength of pure PP is 3.1 kJ / m2. The fracture cross section was analyzed using SEM and the micrograms are shown in Figs. 9A and B. The low microgram magnification (Figure 9A) indicates that the fracture started at a distance (about 300 mm) from the notch line (the white arrow in Figure 9A) and propagated outwards towards the surface of the sample.
[0097] The fracture initiation point was the weakest point and failed for the first time with concentrated stress. In the Izod impact test, the pendulum acts quickly on the notch side of the specimen, resulting in higher strain rate compared to the tensile test. At this high strain rate, the fracture morphology tends to be more fragile. No crazing-tearing or fibrillation morphology was observed. Under this fragile break, the spherolitic morphology of PP can be easily observed on the surface (Figure 9B). The addition of 6 wt% of CNFs in PP slightly decreased the impact strength to 3.0 kJ/m2, which is not statistically significantly different from pure PP. The morphology of the fracture surface was completely changed. Fragile and partial atrial was observed on the surface (Figure 9C). The fracture initiation point is difficult to estimate under this situation.
[0098] According to the load applied by the pendulum, non-consistent movements between PP molecules and CNFs tend to create empty spaces. As the deformation proceeded, empty coalescence finally took place, leading to atrial failure at the interface of CNFs and PP. On the fracture surface shown in FIGURE 9C, a large number of CNFs are exposed without any restriction. It looks like the CNFs lying on top of the polymer matrix. Simultaneously, the incompatibility between CNFs and PP created separate surfaces and voids originally in the composite, facilitating the debonding process between CNFs and PP under load and leading to a possible lower impact strength. The separate surfaces and holes between CNFs and polymer matrix can be easily observed at the highest fracture microgram magnification shown in FIGURE 9D. Well dispersed CNFs in PP is also seen in the fracture micrograms of FIGURE 9C. Further MAPP emulsion treated CNFs in PP did not change impact strength significantly compared to pure PP and unblemished CNFs reinforced PP (Table 3). Previous studies on PP reinforced CNFs showed serious degradation in impact strength at 6 wt. Level % charge (see Yang and other impact resistance analysis of the characteristic model of polypropylene nanofibril-filled composite cellulose, 2011, composites: Part A, 42: 2028-2035). In contrast, in the present example, impact strength remained at the same level with pure PP. Without wishing to be held to a particular theory, it is possible that the superior dispersion of dry CNFs in PP achieved using the master batch compounding process may be responsible, at least in part, for this observed increase in impact strength.
[0099] The fracture morphologies of PP + MAPP_CNF are shown in FIGs 9E and F. Good dispersion of MAPP_CNF was also observed. Similar to the sample of pristine PP reinforced CNFs, brittle fracture and a large amount of exposed CNFs are observed on the surface. However, close-up fracture surface examination of PP + MAPP_CNF indicated that a proportion of CNFs is bound with the polymer matrix (FIGURE 9F). MAPP emulsion treatment on CNFs built this interfacial adhesion. In general, the interfacial adhesion between the reinforcements and the matrix has a significant effect on composite impact strength (see Fu et al., 2008). Strong adhesion generally leads to high impact strength. In this case, however, only a very small amount of interfacial adhesion was built between CNFs and PP and did not increase impact strength. The different particle size distributions of MAPP_CNFs and CNFs may also partially balance the effect of MAPP treatment.
Surprisingly, the addition of 2 wt% MAPP pellets of pure PP significantly increased the impact strength of PP 3.1-3.5 kJ/m2 (approximately a 13%) improvement. MAPP pellet is maleic anhydride grafted onto low molecular weight PP with very high melt flow index (115 g / 10 minutes at 190 °C, with a load of 2.16 kg). In addition to MAPP pellets in PP decreased the MFI of PP from 7.2 to 9.3 g / 10 minutes. The fracture surface of PP + MAPP was examined using SEM and micrograms are shown in Figs. 10A, C, and E. Similar to pure PP, the fracture started at a distance of about 300 µm from the notch line and propagated towards the surface of the specimen (Figure 10A). The low microgram magnification of PP + MAPP (Figure 10A) also shows that a similar brittle failure mode to pure PP was observed except for a number of additional white areas included (white circular area in FIGURE 10A). Close-up examination of the white circular area using SEM obtained the micrograms of FIGURE 10C and E. Materials with the dendritic crystal form in dimensions of several micron meters are observed.
[00101] The effect of adding MAPP on the crystallization behavior of PP has been previously studied, and it is thought that MAPP functions as a nucleating agent in PP and influences PP crystallization (see Seo et al., The study of crystallization behavior of maleic anhydride grafted polypropylene and polypropylene, 2000, Polymer, 41: 2639-2646). The dendritic form material may represent the crystal structure change in the mixture of PP and MAPP that possibly leads to improved impact strength of PP. The crystal structure change by adding MAPP to PP may also explain the increase in the flexural MOE and flexural strength of PP + MAPP. When compared to PP + MAPP, composite consisted of PP, MAPP pellets, and CNFs showed a higher impact strength (3.8 kJ/m2). It is about 23% higher than that of pure PP and 27% higher than pristine CNFs reinforced PP. The cross-sectional fracture morphologies are shown in Figs. 10B, D, and F. The fracture morphology in FIGURE 10B showed fragile failure mode with no observable starting point fracture, indicating that there may be no stress concentration point during the impact test and good dispersion of CNFs. Significantly fewer exposed CNFs are observed. No separate surface and hole is observed. The micrograms WITHOUT higher magnification shown in Figs. 10D and F indicated that strong interfacial adhesion was established. After the impact test, splitting of the CNFs was still observed (FIGURE 10D). Therefore, the impact strength of PP + MAPP + CNF was significantly increased compared to all other composite materials.
[00102] In this example, the concept of masterbatching was used to prepare cellulose nanofibrils (CNFs) polypropylene (PP) nano-composites reinforced through an extrusion process. As described above, two methods were used to modify CNFs by polypropylene grafted maleic anhydride (MAPP): treatment of treatment emulsions and sediment. The first method was the in situ modification of CNFs in the original suspension with MAPP emulsion during the spray drying process. The second method was carried out using MAPP pellets when the mixture spray dried with PP CNFs during the extrusion process. As described above, small differences in particle size distribution were observed for crystalline CNFs and MAPP emulsion treated CNFs. Pure PP had the lowest melt flow index, while the granulate mixture of PP and MAPP had the highest melt flow index. The melt flow indices of all composite CNFs were fonded to be localized between the PP and the granulate mixture of PP and MAPP. When compared to pure PP, addition of CNFs (treated and untreated) in PP resulted in an increase in elastic modulus of elasticity (MOE), tensile strength, flexural strength MOE, and flexural strength while sustained or slightly improved the impact resistance. The best mechanical properties observed in this Example were obtained for composites comprising PP, pellets and MAPP CNFs (PP + MAPP + CNF). The MOE tensile and tensile strength were 1.94 GPa and 32.8 MPa, which represents about 36% and 11% improvement compared to MOE (1.43 GPa) and tensile strength (29.5 MPa) of pure PP. The flexion MOE of PP + MAPP + CNF (1.63 GPa) was about 21% higher than that of pure PP. The highest flexural strengths were obtained for pristine CNFs reinforced PP (52.4 MPa), which is not significantly different from that of PP++ CNF MAPP (50.1MPa). Composed of PP + MAPP + CNF also has the highest impact strength of 3.8 kJ / m2. This value is about 23 % higher than that of pure PP (3.1 kJ / m2). Examination of the fracture morphology described above indicates that a good dispersion of CNFs in the polymer matrix can be achieved through the masterbatching process. MAPP treatments (either emulsion or pellet treatment) improved the interfacial adhesion between CNFs and PP.Example 2
[00103] In this Example, cellulose nanoparticles (CNP) were prepared from cellulose suspensions in accordance with patent-pending technology by Advanced Composite Structures and University of Maine Center, as described in US Patent 8,372,320 . The average size of CNP varied within a few micrometers, including a significant amount of nano-sized particles (at least 30%). The CNP was processed using conventional polymer processing methods, impact-modified polypropylene (IMPP) as a polymer matrix. The CNP loading level in this Example was 6% by weight, which was pre-coated with grafted polypropylene maleic anhydride (PP-g-MA), a coupling agent, via a master batch treatment process similar to described above in Example 1 . In the mechanical properties test, the results revealed that not only the stiffness of the resulting composite was improved, but also the strength was too much. The maximums were observed increases of 35.66% (stiffness) and 11.25% (strength) for tensile properties, 20.74% (stiffness) and 6.73% (strength) for bending properties, and 23.45 % for impact resistivity. Without intending to be held to a particular theory, it is possible that the improvement can be activated from at least two effects, the first being the addition of nano-sized additives, and the second being a processing modified for coat the coupling agent onto the surfaces of the additives.
[00104] In general, the addition of solid additives or fillers to thermoplastic composite materials increase stiffness with a critical load level, such as two digit percentiles, due to the much higher modulus of fillers/additives, in comparison. with the matrix polymer(s) themselves. However, the strength of a compound usually cannot be increased easily due to poor compatibility between fillers and additives/polymer matrices. Even with good compatibility, a long filler/additive aspect ratio is required. Furthermore, high loading levels of fillers/additives increase viscosity leading to more energy requirements and lower production rate. The shown increases in the mechanical properties of the composites resulting in this example using a relatively small percentage (6%) of the additives are therefore very important and surprising. An advantage provided by various embodiments include a relatively low cost, given the small amounts of filler/additive used, in fact it can be competitive CNP for carbon nanotubes or even carbon fibers or glass fibers. A second advantage is the use of cellulose, which is an environmentally friendly additive.Effects of Using Coupling Agents with Additives
[00105] A master batch was prepared using CNP with PP-g-MA, a coupling agent, in an extrusion process. The master batch was re-combined with the IMPP, resulting in 6% by weight. of the CNP charge level and 2% by weight. of PP-g-MA. Mechanical properties are shown in FIGURE 11. For the sample with CNP coupled with PP-g-MA, improvements were observed in all flexion, tensile and impact properties. (IMPP-MB: impact modified polypropylene processed by master batch, IMPP-CNP: IMPP filled with CNP only, IMPP-g-MAPP: IMPP filled with CNP and PP-g-MA). Comparison of Mechanical Properties of Various Composites of IMPP
[00106] Several compounds have been prepared using various cellulosic additives to compare the effects on mechanical properties. Sample nomenclatures are shown in Table 4. Samples with CNF were prepared using the Mater batch process. It is shown in Figures 12 through 14 that all tested mechanical properties, including tensile, bending, impact strength and properties, were significantly improved in the NFC-filled sample by the batch preparation method. Table 4. Nomenclature of Samples

[00107] The Examples presented here describe, among other things, exemplary methods of preparing composite materials with improved properties and represent a new way of providing composite materials with desirable mechanical and other characteristics while requiring filling significantly less than other methods. Equivalents and Scope
[00108] Those skilled in the art will recognize, or are able to ascertain employing no more than the route of experimentation, many equivalents to the specific embodiments of the invention described herein. The scope of the present invention is not intended to be limited to the above Description, but preferably as set forth in the claims that follow:

权利要求:
Claims (16)
[0001]
1. Method, characterized in that it comprises providing the cellulose nanofibrils; associating the cellulose nanofibrils with a copolymer of maleic anhydride (MA) to form a nanofibril-MA copolymer mixture; preparing the nanofibril copolymer mixture -MA for addition to a matrix polymer; wherein the preparation step comprises drying the nanofibril-MA copolymer mixture; eforming a composite by associating the nanofibril-MA copolymer mixtures with the matrix polymer, wherein the amount of cellulose nanofibrils in the composite is between 3% and 50% by weight of the composite.
[0002]
2. Method according to claim 1, characterized in that drying is spray drying.
[0003]
3. Method according to claim 1, characterized in that the preparation step comprises drying the nanofibril-MA copolymer mixture; cooling the dry nanofibril-MA copolymer mixture; granulate the dry nanofibril-MA copolymer blend to form a nanofibril-MA copolymer master batch.
[0004]
4. Method according to claim 1, characterized in that the step of associating the cellulose nanofibril with a copolymer of maleic anhydride (MA) to form a mixture of nanofibril-MA copolymer occurs at a temperature between 130°C. °C and 220 °C inclusive.
[0005]
5. Method according to claim 1, characterized in that the step of associating the cellulose nanofibril with a maleic anhydride (MA) copolymer comprises the mixing of the cellulose nanofibrils and maleic anhydride (MA) copolymer of between 1 minute and 60 minutes inclusive.
[0006]
6. Method according to claim 1, characterized in that the cellulose nanofibrils are in solution at the time of initiation of the step of association of the cellulose nanofibril with a copolymer of maleic anhydride (MA).
[0007]
7. Method according to claim 1, characterized in that the maleic anhydride copolymer comprises the dispersed phase of an emulsion at the time of initiation of the step of associating the cellulose nanofibril with a maleic anhydride (MA) copolymer .
[0008]
8. Method according to claim 1, characterized in that the cellulose nanofibrils are substantially dry at the time of initiation of the step of associating the cellulose nanofibril with a maleic anhydride (MA) copolymer to form a copolymer mixture of nanofibril-MA.
[0009]
9. Method according to claim 1, characterized in that the composite is defined as having an impact strength that is greater than that of a composite consisting of the matrix polymer and the cellulose nanofibrils.
[0010]
10. Method according to claim 9, CHARACTERIZED by the fact that the impact strength of the composite is at least 20% greater than that of a composite consisting of the matrix polymer and the cellulose nanofibrils.
[0011]
11. Method according to claim 10, characterized in that the composite is defined as having a tensile modulus of elasticity at least 35% greater than that of a composite consisting of the matrix polymer and the cellulose nanofibrils.
[0012]
12. Method according to claim 11, characterized in that the composite is defined as having a tensile strength at least 10% greater than that of a composite consisting of the matrix polymer and the cellulose nanofibrils.
[0013]
13. Method according to claim 12, characterized in that the maleic anhydride polymer is selected from an olefin polymer of maleic anhydride and a polystyrene maleic anhydride.
[0014]
14. Method according to claim 13, characterized in that an olefin copolymer of maleic anhydride is maleic anhydride polypropylene or polyethylene maleic anhydride.
[0015]
15. Method according to claim 14, characterized in that the composite is formed through an extrusion, compression molding, injection molding, and/or fused layer molding process.
[0016]
16. Composite material, characterized in that it is produced according to a method as defined in claim 1.

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同族专利:

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公开号 | 公开日

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BR112016000813A2|2017-07-25|

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US20160152811A1|2016-06-02|

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ES2788658T3|2020-10-22|

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EP3022255B1|2020-02-12|

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CA2918313C|2021-07-13|

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US10280294B2|2019-05-07|

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WO2015009972A1|2015-01-22|

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EP3022255A1|2016-05-25|

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CA2918313A1|2015-01-22|

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EP3022255A4|2017-04-12|

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法律状态:
2019-12-10| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-06-22| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-07-20| B350| Update of information on the portal [chapter 15.35 patent gazette]|

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2021-08-03| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 17/07/2014, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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US201361847751P| true| 2013-07-18|2013-07-18|

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US61/847,751|2013-07-18|

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PCT/US2014/047100|WO2015009972A1|2013-07-18|2014-07-17|Nanofibril-polymer composites|

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