巴西专利BR102017023556A2 ABSORBENT POLYMERS AND METHODS FOR YOUR PRODUCTION AND USES

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专利摘要:
Absorbent polymers and methods for their production and uses The present invention relates to absorbent polymers made from beta-propiolactone and methods of producing such polymers. These absorbent polymers may be crosslinked. beta-propiolactone may be derived from ethylene oxide and carbon monoxide. The absorbent polymer may be biobased and / or biodegradable. absorbent polymers can be used for diapers, adult incontinence products and feminine hygiene products, as well as for agricultural applications.
公开号:BR102017023556A2
申请号:R102017023556-4
申请日:2017-10-31
公开日:2019-04-16
发明作者:Sadesh H. Sookraj；Alexander Tseitlin；Han Lee；Konstantin A. Pokrovski
申请人:Novomer, Inc.；
IPC主号:

专利说明:

ABSORBENT POLYMERS AND METHODS FOR THEIR PRODUCTION AND ITS USES
Cross Reference to Related Orders [001] This patent application claims priority to provisional US Patent Application No. 62 / 416,623, filed on November 2, 2016, which is hereby incorporated by reference in its entirety.
Field of the Invention [002] The present invention relates to polymeric materials in general and, more specifically, to polymeric materials suitable for use as absorbent materials, and methods for their production.
Fundamentals [003] Superabsorbent polymers are polymeric materials that can absorb and retain large amounts of water or aqueous solutions. Such polymeric materials are used extensively for the manufacture of diapers, adult incontinence products and feminine hygiene products, as well as in agricultural applications.
[004] Superabsorbent polymers are commonly produced from the polymerization of acrylic acid. However, due to the fluctuating price of acrylic acid and the shortage of supply, there is a desire in the art to produce polymeric materials with adsorbent properties from alternative sources. In particular, there is a need in the art to produce bio-based biodegradable polymeric materials with absorbent properties, obtained from renewable sources.
Brief Summary [005] Polymeric materials with
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2/30 absorbent properties, and methods for its production, that address the need in the art.
Such polymeric materials can be obtained from betapropiolactone, which can be derived from renewable sources, such as ethylene oxide and bio-based carbon monoxide.
[006] In some respects, a method of producing a cross-linked polymer is provided, which comprises the combination of beta-propiolactone and a cross-linking agent to produce the cross-linked polymer, wherein the cross-linked polymer comprises a partially polyacrylic acid backbone neutralized and a plurality of polypropiolactone side chains, and crosslinking portions. In some variations of the above, the polypropiolactone side chains independently have a structure of the general formula (CH2CH2 (C = O) -O) n ^- M ⁺ , where: n is an integer from 1 to 10 including; and M ⁺ is an alkali metal, a crosslinking moiety or H ⁺ .
[007] In certain aspects, a method of producing a crosslinked polymer is provided, which comprises the combination of beta-propiolactone and a crosslinking agent in the presence of a metal cation to produce the crosslinked polymer, wherein the crosslinked polymer comprises a main structure of partially neutralized polyacrylic acid and a plurality of polypropiolactone side chains, and crosslinking portions. In certain variations, the source of the metallic cation is a metallic salt. For example, in one variation, the metal salt may be a metal acrylate.
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3/30 [008] In certain respects, a method of producing a crosslinked polymer is provided, which comprises reacting a low molecular weight polypropiolactone with a radical polymerization initiator and a crosslinking agent, wherein the polypropiolactone of low molecular weight has a formula CH2 = CH2- (C = O) -O- (CH2CH2 (C = O) -O) nM⁺, where n is an integer from 1 to 10 including; in⁺ is an alkali metal, a cross-linking portion or H⁺.
[009] In other respects, a polymer produced according to any of the methods described herein is provided.
[010] In some aspects, a polymer is provided comprising a poly (sodium acrylate / acrylic acid) backbone and a plurality of polypropiolactone side chains attached to the backbone. In some embodiments, the polymer is cross-linked. In some variations of the above, the polymer is bio-based and / or biodegradable.
[011] The polymers described herein, or produced according to the methods described here, may be suitable for use as an absorbent article (for example, for diapers, adult incontinence products or feminine hygiene products) or as agricultural products ( for example, for agricultural materials and seed coatings).
Description of the Figures [012] The present application can be better understood by reference to the description below, together with the accompanying figures, in which like parts can be referred to by like numbers.
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4/30 [013] FIGS. 1-3 illustrate exemplary processes for producing the polymer described herein from betapropiolactone.
[014] FIG. 4 represents an exemplary process for producing beta-propiolactone from ethylene oxide and carbon monoxide.
[015] FIG. 5 represents an exemplary polymer comprising a poly (sodium acrylate / acrylic acid) backbone and a plurality of polypropiolactone side chains attached to the backbone.
[016] FIG. 6 represents an exemplary polymer comprising a poly (sodium acrylate / acrylic acid) backbone and a plurality of cross-linked polypropiolactone side chains attached to the backbone. The type of crosslinking in such a polymer will depend on the crosslinking agent used.
[017] FIG . 7A represents one polymer reticulate exemplary, where N, N'-methylenebis (acrylamide) is the crosslinking agent. [018] FIG . 7B represents one polymer reticulate exemplary on what carbonate in ethylene is the agent crosslinking.[019] FIG . 7C represents one polymer reticulate exemplary, in which acrylate in aluminum is the agent crosslinking.[020] FIG . 7D represents one polymer reticulate
exemplary, in which diglycidyl ethylene glycol is the crosslinking agent.
Detailed Description [021] The description that follows presents examples of
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5/30 methods, parameters and the like.
However, it should be recognized that this description should not be considered a limitation on the scope of the present invention, on the contrary, it is provided as a description of exemplary modalities.
[022] Polymers that have absorbent properties are provided here.
In some respects, such polymers are produced from beta-propiolactone.
beta-propiolactone can be produced from the carbonylation of ethylene oxide.
When ethylene oxide and carbon monoxide are obtained from renewable sources, the polymers described herein can be bio-based polymers. In addition, the polymers described herein can be biodegradable. Such superabsorbent polymers can be used for diapers, adult incontinence products and feminine hygiene products, maintaining or improving the performance of such products.
[023] The methods for producing such absorbent polymers, and the structure and properties of such absorbent polymers are described in more detail below.
Methods of Production of Absorbent Polymers [024] In some respects, polymers or polymer compositions produced from beta-propiolactone are provided herein. Such polymers comprise a poly (sodium acrylate / acrylic acid) backbone and a plurality of polypropiolactone side chains attached to the backbone.
[025] In some embodiments, a method of producing a polymer composition is provided, which comprises the combination of beta-propiolactone and a curing agent.
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6/30 crosslinking.
The polymer composition comprises a cross-linked polymer.
[026]
With reference to FIG.
1, the process
100 is an exemplary process for producing the crosslinked polymer
110 from beta-propiolactone
102 and the crosslinking agent 104.
The cross-linked polymer
The resulting 110 can comprise a partially neutralized polyacrylic acid backbone and a plurality of crosslinking side chains.
[027] In some variations, the polypropiolactone, and polypropiolactone side chains independently have a structure of the formula - (CH2CH2 (C = O) -O) n ^- M ⁺ , where:
n is an integer from 1 to 10 inclusive; and
M ⁺ is an alkali metal, a cross-linking portion or H ⁺ .
[028] The length of the polypropiolactone side chains can vary and affect the absorption of the polymer.
[029] In some variations, the crosslinking portions connect carboxylic end groups of at least a portion of the polypropiolactone side chains. In other variations, the crosslinking portions connect neutralized carboxylate groups from at least a portion of the polypropiolactone side chains. In yet other variations, the crosslinking portions connect at least a part of the main structure of partially neutralized polyacrylic acid.
[030] In other embodiments, a method of producing a cross-linked polymer is provided, which comprises the combination of beta-propiolactone, a cross-linking agent
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7/30 and an initiator. In some variations, the initiator is an ionic initiator.
Thus, in some variations, with reference to FIG.
2, process 200 is an exemplary process for producing cross-linked polymer 210 from beta-propiolactone 202, the cross-linking agent
204 and ionic initiator 206.
[031] In other variations, the initiator is a radical initiator. Thus, in some variations, with reference to FIG. 3, process 300 is an exemplary process for
to produce the polymer lattice 310 to leave gives beta- propiolactone 302, the crosslinking agent 304 it's the initiator of radical 306. [032] Must be generally understood what, in others variations examples, the processes 100, 200 or 300 may include one or more additional reagents and / or one or
more additional steps. For example, in some variations, a solvent can be used for the polymerization reaction. In other variations, the polymerization reaction is carried out pure. In still other variations, processes 100, 200 or 300 may also include increasing the crosslinking of the polymer. For example, in a single variation, the crosslinked polymer 110, 210 or 310 is combined with additional crosslinking agent (s) to increase the surface crosslinking of the polymer.
[033] In other embodiments, a method of producing a crosslinked polymer is provided, comprising reacting a low molecular weight polypropiolactone with a radical polymerization initiator and a crosslinking agent, wherein the low molecular weight polypropiolactone has
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8/30 a formula CH2 = CH2- (C = O) -O- (CH2CH2 (C = O) -O) n ^- M ⁺ , where n is an integer from 1 to 10 inclusive; and
M ⁺ is an alkali metal, a crosslinking unit or H ⁺ .
[034] In some variations of the previous modality, low molecular weight polypropiolactone can be obtained from the polymerization of beta-propiolactone.
[035] Beta-propiolactone, cross-linking agent and initiators are described in more detail below.
Beta-Propiolactone [036] Beta-propiolactone can be produced by any suitable methods or techniques known in the art. For example, in some variations, with reference to FIG. 4, beta-propiolactone 410 is produced from ethylene oxide 402 and carbon monoxide 404. Ethylene oxide undergoes carbonylation in the presence of a carbonylation catalyst and optionally a solvent.
[037] Thus, in some aspects, a method of producing a cross-linked polymer is provided, which comprises: carbonylation of ethylene oxide to produce beta-propiolactone; and combining beta-propiolactone and a cross-linking agent to produce the cross-linked polymer. In some variations, the method comprises: combining ethylene oxide, carbon monoxide, a carbonylation catalyst and optionally a solvent to produce beta-propiolactone; and combining beta-propiolactone and a cross-linking agent to produce the cross-linked polymer. In one variation, the method comprises: a combination of ethylene oxide, carbon monoxide, a carbonylation catalyst and a solvent to produce beta
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9/30 propiolactone; and combining beta-propiolactone and a cross-linking agent to produce the cross-linked polymer.
[038] Beta-propiolactone can be isolated prior to polymerization to produce the polymers described herein. Thus, in some variations, a method of producing a crosslinked polymer is provided, which comprises: carbonylation of ethylene oxide to produce betapropiolactone; isolating at least a part of the betapropiolactone produced and combining the isolated beta-propiolactone and a cross-linking agent to produce the cross-linked polymer. In some variations, the method comprises: a combination of ethylene oxide, carbon monoxide, a carbonylation catalyst and optionally a solvent to produce beta-propiolactone; isolating at least a part of the produced beta-propiolactone and combining the isolated beta-propiolactone and a cross-linking agent to produce the cross-linked polymer. In one variation, the method comprises: a combination of ethylene oxide, carbon monoxide, a carbonylation catalyst and a solvent to produce beta-propiolactone; isolating at least a part of the produced beta-propiolactone and combining the isolated beta-propiolactone and a cross-linking agent to produce the cross-linked polymer.
[039] In some variations of the above, carbon monoxide is supplied in gaseous form. In other variations of the previous content, ethylene oxide is supplied in gaseous form. In certain variations, gaseous ethylene oxide is converted into a liquid form and combined with a solvent, a carbonylation catalyst and gaseous carbon monoxide in the reactor.
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10/30 [040] Any suitable carbonylation catalysts can be used to produce beta-propiolactone. For example, in some variations, the carbonylation catalyst comprises a metallic carbonyl compound. In certain variations, the carbonylation catalyst is a solidly supported metallic carbonyl compound. Suitable carbonylation catalysts are described, for example, in WO 2010/118128. In some variations, the carbonylation catalyst comprises [(TPP) Al] [Co (CO) 4], [(ClTPP) Al] [Co (CO) 4], [(TPP) Cr] [Co (CO) 4] , [(ClTPP) Cr] [Co (CO) 4], [(salcy) Cr] [Co (CO) 4], [(salph) Cr] [Co (CO) 4], or [(salph) Al] [Co (CO) 4]. It should generally be understood that TPP refers to tetrafenilporphyrin; ClTPP refers to mesotetra (4-chlorophenyl) porphyrin); Salcy refers to (N, N'bis (3,5-di-tert-butylsalicylidene) -1,2-diaminocyclohexane); and salph refers to (N, N'-bis (salicylidene) -phenylenediamine).
[041] Any suitable solvents can be used to produce beta-propiolactone. In some variations, the solvent comprises an ether solvent. In one variation, the solvent comprises tetrahydrofuran.
[042] In one variation, the method comprises: supply of gaseous ethylene oxide;
conversion of gaseous ethylene oxide under suitable pressure conditions to produce liquid ethylene oxide;
combining liquid ethylene oxide with a solvent, a carbonylation catalyst and gaseous carbon monoxide to produce beta-propiolactone;
isolation of at least part of the beta
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11/30 propiolactone produced;
combination of the isolated beta-propiolactone and a cross-linking agent to produce the cross-linked polymer.
Crosslinking Agents [043] Various crosslinking agents can be used in the methods described herein. Any combinations of the crosslinking agents described herein can also be used.
[044] In some embodiments, the crosslinking agent comprises an acrylamide compound, a metal acrylate compound, an organic carbonate compound, a diglycidyl compound or an organic vinyl compound comprising two or more vinyl groups.
[045] In other embodiments, the crosslinking agent comprises a silane compound. In one embodiment, the silane compound has a structure of the formula Y3SiR ^to N ⁺ R ¹ R ² R ³ X ^- , where:
Y is a hydrolyzable radical;
R ^a is a divalent hydrocarbon radical;
each of R ¹ , R ² and R ³ is independently:
a saturated or unsaturated hydrocarbon radical, or a saturated or unsaturated organic radical comprising carbon, hydrogen and at least one heteroatom selected from the group consisting of oxygen, sulfur and nitrogen; and
X ^- is an anion.
[046] In some variations of the silane compound, R ^a is a divalent hydrocarbon radical with 1 to 6 carbon atoms. In certain variations of the silane compound, each of R ¹ , R ² and R ³ is independently a radical
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12/30 saturated or unsaturated organic which comprises (i) carbon, hydrogen and oxygen, (ii) carbon, hydrogen and sulfur, or (iii) or carbon, hydrogen and nitrogen. In one variation, each of R ¹ , R ² and R ³ is independently a saturated or unsaturated organic radical consisting of (i) carbon, hydrogen and oxygen; (ii) carbon, hydrogen and sulfur; or (iii) or carbon, hydrogen and nitrogen.
[047] In other variants of the silane compound, X^- it is a halide, acetate or tosylate. In some variations, X^- it is chloride, bromide, fluoride or iodide. In another variation, Xis acetate. In yet another variation, X^- is tosylate.
[048] In other embodiments, the crosslinking agent has at least two functional groups that can react with the carboxyl, carboxylate, vinyl or other reactive groups on the polymer chain to crosslink polymer chains on the surface or proximity to the surface of the particles of polymer.
[049] In some variations, the crosslinking agent is an organic compound that comprises two or more vinyl groups. In other variations, the cross-linking agent is an organic compound comprising a Group 2, 3 or 4 metal cation. In other variations, the cross-linking agent is an organic carbonate. In still other variations, the cross-linking agent is an organic compound that comprises two or more glycidyl groups.
[050] In other embodiments, the crosslinking agent comprises a polyol or a polyglycidyl ether.
[051] In still other embodiments, the cross-linking agent comprises a polysaccharide.
[052] In some variations, the crosslinking agent is the
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13/30 ethylene glycol dimethacrylate, diethylene glycol diacrylate, allyl methacrylate, 1,1,1-trimethylpropane triacrylate, tetraaloxyethane trialylamine, N, N'-methylenebis (acrylamide), aluminum acrylate, ethylene carbonate or diglylate ethylene glycol ether. In one variation, the crosslinking agent is N, N'methylenobis (acrylamide). In other variations, the crosslinking agent is ethyl carbonate. In other variations, the crosslinking agent is aluminum acrylate. In still other variations, the cross-linking agent is diglycidyl ethylene glycol.
Primers [053] In one variation, the initiator is an ionic initiator and / or a radical initiator. Any combinations of the primers described herein can also be used.
[054] For example, with reference to FIG. 2, process 200 is an exemplary process for producing cross-linked polymer 210 from beta-propiolactone 202, cross-linking agent 204 and ionic initiator 206.
[055] In some variations, the ionic initiator comprises an alkali metal salt or an alkaline earth metal salt. In certain variations, the ionic initiator comprises an alkali metal carboxylate salt or an alkaline earth metal salt. In one variation, the ionic initiator is an alkali metal salt.
[056] In other variations, the ionic initiator has a structure of the general formula CH ₂ = CH ₂ CO ₂ ^- Z ⁺ , where Z ⁺ is an alkali metal, an alkaline earth metal, ammonium, a quaternary ammonium cation or phosphonium. In certain
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14/30
variations, the ionic initiator has a structure gives formula general CH2 = CH2CO2 ^- Z ⁺ , where Z ⁺ it's a cation in ammonium quaternary. In a variation, the cation in ammonium quaternary is a quaternary ammonium cation in alkyl bottom. [057] In other variations, the initiator ionic is acrylate sodium or acrylate of potassium. In certain
variations, the ionic initiator is a methacrylate. In one variation, the ionic initiator is sodium methacrylate or potassium methacrylate.
[058] In another example, with reference to FIG. 3, process 300 is an exemplary process for producing crosslinked polymer 310 from beta-propiolactone 302, crosslinking agent 304 and radical initiator 306.
[059] In some variations, the radical initiator comprises a peroxide, a persulfate or an azo compound. In other variations, the radical initiator is a redox initiator. In certain variations, the radical initiator comprises a hydroperoxide. In one variation, the radical initiator comprises hydrogen peroxide.
Additional Monomeric Compounds [060] The beta-propiolactone and the cross-linking agent, and optionally the initiators, can be additionally combined with an additional monomeric compound. Thus, in some embodiments, a method of producing a cross-linked polymer is provided, which comprises the combination of beta-propiolactone, a cross-linking agent, optionally a initiator, and an additional monomeric compound to produce the cross-linked polymer.
[061] In other modalities, a method is provided
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15/30 to produce a crosslinked polymer, which comprises reacting a low molecular weight polypropiolactone with a radical polymerization initiator, a crosslinking agent and an additional monomeric compound, wherein the low molecular weight polypropiolactone has a formula CH2 = CH2- (C = O) -O- (CH2CH2 (C = O) -O) n ^- M ⁺ , where n is an integer from 1 to 10 inclusive; and
M ⁺ is an alkali metal, a cross-linking portion or H ⁺ .
[062] In some variations, the additional monomeric compound is an organic compound comprising at least one vinyl group. In other variations, the additional monomeric compound is an optionally substituted acrylic acid, or a carbohydrate, or any combination thereof. In one variation, the additional monomeric compound is methacrylic acid.
Absorbent Polymers [063] In some respects, polymers produced according to any of the methods described herein are provided. In other respects, a polymer is provided which comprises a poly (sodium acrylate / acrylic acid) backbone and a plurality of polypropiolactone side chains attached to the backbone. An example of such a polymer is illustrated in FIG. 5.
[064] In some variations, the polypropiolactone side chains independently have a structure of the general formula - (CH2CH2 (C = O) -O) n ^- M ⁺ , where:
n is an integer from 1 to 100 inclusive; and
M ⁺ is an alkali metal, a cross-linking portion or H ⁺ .
[065] In certain variations of the previous content, n is a
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16/30 integer from 1 to 50, 1 to 40, 1 to 30, 1 to 20 or 1 to 10 inclusive.
[066] In certain variations of the above, M ⁺ is an alkali metal. In a variation, M ⁺ is Na ⁺ or K ⁺ , or a combination of them. In other variations, M ⁺ is H ⁺ . In still other variations, M ⁺ is an alkali metal, a cross-linking portion. For example, M ⁺ can be any of the crosslinking portions described here in cationic form.
[067] In some variations, the polymers described here are cross-linked. In other aspects, a polymer is provided comprising a backbone of partially neutralized polyacrylic acid and a plurality of polypropiolactone side chains and crosslinking portions.
[068] An example of a crosslinked polymer is shown in FIG. 6. The type of crosslinking that occurs in the polymer shown in FIG. 6 will depend on the types of crosslinking agent used to produce this polymer. For example, FIGs. 7A - 7D illustrate several examples of cross-linked polymers, including N, N'methylenobis (acrylamide) (Figure 7A), ethylene carbonate (Figure 7B), aluminum acrylate (Figure 7C) and diglycidyl ethylene glycol ether (Figure 7D).
Molecular Weight [069] The molecular weight (including the average molecular weight) and the molecular weight distribution can be determined by any suitable techniques or methods known in the art.
[070] In some embodiments, the polymer has an average molecular weight in number of at least 1 million
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17/30
Daltons; at least 1.5 million Daltons; at least 2 million Daltons; at least 2.5 million Daltons or at least 3 million Daltons; or between 1 million Daltons and 3 million Daltons; between 1 million Daltons and 2 million Daltons; or between 1 million Daltons and 1.5 million Daltons.
Particle Size and Particle Size Distribution [071] Particle size (including average particle size) and particle size distribution can be determined by any techniques or methods known in the art.
suitable
[072] In some embodiments, the polymer has a size particle medium higher The 50 pm, higher The 55 pm, higher to 60 pm, higher The 65 pm, higher The 70 pm, higher to 75 pm, higher The 80 pm, higher The 85 pm, higher to 90 pm, greater than 95 pm or greater than 100 pm; or between 50 pm and 500 pm, between 50 pm and 400 pm, enter 50 pm and 300 pm between 50 pm and 200 p m, between 50 pm and 150 pm, enter
100 pm and 500
200 pm and 500 between 300 pm and
500 between pm, pm, pm, or between
400 pm and 500 pm.
[073] In other embodiments, polymer has a particle size distribution between 50 pm and 900 pm, between 50 pm and 850 pm, between 50 pm and
700 pm, between 50 pm and
600 pm, between 50 pm and 500 pm, between pm and 400 pm, between pm and 300 pm, between 50 pm and 200 pm, between 50 pm and 150 pm, between
100 pm and 500 pm, between 200 pm and 500 pm, between 300 pm and 500 pm, or between 400 pm and 500 pm.
[074]
The particle size distribution can be described based on the distribution of more than 50%, 60%, 70%,
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18/30
80% or 90% of the particles. In some variations, the polymer has a particle size distribution of more than 50%, 60%, 70%, 80% or 90% of the particles between 50 pm and 900 pm, between 50 pm and 850 pm, between 50 pm and 700 pm, between 50 pm and 600 pm, between 50 pm and 500 pm, between 50 pm and 400 pm, between 50 pm and 300 pm, between 50 pm and 200 pm, between 50 pm and 150 pm, between 100 pm and 500 pm, between 200 pm and 500 pm, between 300 pm and 500 pm or between 400 pm and 500 pm.
[075] In some respects, polymer compositions produced according to any of the methods described herein are provided. The polymer compositions comprise any of the polymers described herein and may further comprise residual and extractable monomers.
Residual Monomers [076] The content of residual monomers can be of significant importance, particularly for adsorbent polymers used in hygienic applications.
For example, in some variations, the residual monomer content is the residual beta-propiolactone content, or the residual acrylic acid content, or a combination of these. Residual acrylic acid can be derived from betapropiolactone.
[077] The residual monomer content of the polymers described herein can be determined by any suitable methods or techniques known in the art. For example, high performance liquid chromatography (HPLC) can be used to quantify residual monomers.
[078] In some variations, the polymer composition has a residual monomer content of less than 1500 ppm, less than 1000 ppm, less than 900 ppm, less than 800
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19/30 ppm, less than 700 ppm, less than 600 ppm, less than 500 ppm, less than 400 ppm, less than 300 ppm, less than 200 ppm or less than 100 ppm.
Soluble Fraction or Extractable Content [079] The soluble fraction (sol) generally refers to the sum of all water-soluble species, including, for example, unreacted starting materials and other residual monomers. The soluble fraction can be determined by any suitable methods or techniques known in the art. The soluble content can be measured by extracting a sample in water (for example, distilled water) and the sol is often referred to in the art as extractable.
[080] For example, in a variation, the soluble fraction can be measured by extracting a sample in distilled water. A certain amount of the sample is poured into excess water and dispersed with magnetic stirring to achieve equilibrium swelling. The swollen sample is filtered and dried. The weight loss of the sample results in the soluble fraction. See, for example, ZohuriaanMehr, M.J. and Kabiri, Kourosh, Superabsorbent Polymer Materials: A Review, Iranian Polymer Journal, 17 (6), 2008, 465.
[081] In some embodiments that can be combined with the previous content, the polymer composition has a soluble fraction of less than 20%, less than 15%, less than 10%, less than 5%, less than 1% by weight of polymer composition.
[082] The polymer composition can also be described based on its extractable content. Extractables can include, for example, unreacted monomers and all
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20/30 other small molecules that are not the polymer. In some variations, the extractable content of the polymer composition can be expressed as follows:
Extractable content (% by weight) = extractable weight / (total weight of starting materials) [083] In some embodiments that can be combined with the previous content, the polymer composition has an extractable content of less than 20%, less than 15%,
less than 10%, less than 5%, less than 1% by weight gives polymer composition. Absorbency Under Load (AUL) [084] Absorbance in general refers to the amount in liquid that a material can to contain. THE absorbency under
load in general refers to the absorbent capacity of a material, as measured under an applied load. Absorption under load can be determined by any suitable methods or techniques known in the art. For example, in one variation, absorbance under load can be determined by dispersing 0.2 g of a given absorbent material in a burette-like device over an untwisted fabric, and placing a load of 20 g / cm ² on a cylinder and allowing artificial urine to be absorbed by the resin for 30 minutes. This test can determine the volume of artificial urine absorbed. Other methods known in the art can be used to determine absorption under load. See, for example, Zohuriaan-Mehr, MJ and Kabiri, Kourosh, Superabsorbent Polymer Materials: A Review ”, Iranian Polymer Journal, 17 (6), 2008, 463.
[085] In some variations, the polymer or composition of
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21/30 polymer has an absorption under load greater than 20 g / g, greater than 25 g / g, greater than 30 g / g, greater than 35 g / g, greater than 40 g / g, greater than 45 g / g or greater than 50 g / g; or between 10 g / g and 50 g / g, between 10 g / g and 40 g / g, between 10 g / g and 25 g / g, between 20 g / g and 50 g / g, or between 25 g / g and 40 g / g g.
[086] In other variations, the polymer or polymer composition absorbs more than 100 times, more than 150 times, more than 200 times, more than 250 times, more than 300 times, more than 400 times or more than 500 times the weight dry polymer or polymer composition when in contact with a liquid. In still other variations, the polymer or polymer composition absorbs between 100 times and 400 times, between 150 times and 400 times, or between 150 times and 300 times the dry weight of the polymer or polymer composition, when in contact with a liquid.
Absorbance Rate [087] The absorbance rate refers to the speed at which a liquid is absorbed. This liquid can be, for example, water. The rate of absorbance can be determined by any suitable methods or techniques known in the art. For example, in a variation, the absorbency rate can be determined by swelling kinetics methods. See, for example, E. Southern, A.G. Thomas, Trans. Faraday Soc. 63, 1913 (1967).
[088] In some variations, the polymer or polymer composition has an absorbance rate greater than 10 g / g, greater than 15 g / g or greater than 20 g / g; or between 10 g / g and 50 g / g, between 15 g / g and 50 g / g, between 15
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22/30 g / g and 40 g / g, between 15 g / g and 30 g / g, or between 15 g / g and 20 g / g. In a variation of the above, the absorbency rate is measured at 0.3 psi (2068.43 Pa) at 5 min.
Swelling Capacity [089] Swelling capacity is a measure of absorbency. The swelling capacity can also be referred to in the art as centrifuge holding capacity ”. The swelling capacity can be determined by any suitable methods or techniques known in the art. See, for example, Zohuriaan-Mehr, M.J. and Kabiri, Kourosh, Superabsorbent Polymer Materials: A Review ”, Iranian Polymer Journal, 17 (6), 2008, 462-463. For example, in some variations, the swelling capacity can be determined by the tea bag method. A polymer sample can be placed in a tea bag and the bag is dipped in an excessive amount of water or saline for one hour to reach the
swelling of balance. THE solution in excess is removed by hanging the bag until what none ping liquid. The tea bag is heavy (W1) and the capacity of swelling is calculated from a deal with the equation (1) below. Sc = (W1-W0) / WqEquation (1)
[090] Other methods known in the art can also be used to measure swelling capacity. In other variations, the centrifuge method can also be used to measure swelling capacity. For example, 0.2 g (Wi) of the polymer sample is placed in a bag made of non-woven fabric. The bag is immersed in 100 mL of saline solution for half an hour at room temperature.
Petition 870170103516, of 12/29/2017, p. 27/41
23/30 environment. Then the bag is removed and then the excess solution is removed with a centrifugal separator. Then, the weight of the bag (W2) is measured. The same steps are performed with an empty bag, and the weight of the bag (W0) is measured. The swelling capacity is then calculated by equation (2) below.
Sc = (W2-W0-W1) / W1 Equation (2) [091] In some modalities that can be combined with the previous content, the polymer or polymer composition has a swelling capacity greater than 30 g / g, greater than 35 g / g, greater than 40 g / g, greater than 45 g / g or greater than 50 g / g; or between 30 g / g and 50 g / g, between 30 g / g and 40 g / g, or between 30 g / g and 35 g / g.
[092] In general, it should be understood that any properties of the polymers or polymer compositions described herein can be combined as if each and every combination of properties were individually listed. For example, in a variation, the polymer or composition of
polymer has: (i) an absorption under charge in between 12 g / g e 22 g / g; and (ii) an absorbance speed in between 15 g ^/ g ^e 20 g / g. Biological Content [093] In some variations of what was exposed
previously, the polymer or polymer composition has a biological content greater than 0% and less than 100%. In certain variations of the foregoing content, the polymer or polymer composition has a biological content of at least 10%, at least 20%, at least 30%, at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 95%, at least 96%, at least
Petition 870170103516, of 12/29/2017, p. 28/41
24/30 minus 97%, at least 98%, at least 99%, at least 99.5%, at least 99.9%, at least 99.99%, or 100%.
[094] In some variations, the biological content (also known as bio-based content ”) can be determined based on the following:
% Biological content or bio-based content = [Biological carbon (organic)] / [Total carbon (organic)] * 100% as determined by ASTM D6866 (Standard Test Methods for Determining the Bio-Based Content of Solid, Liquid and Gas using Radiocarbon Analysis).
[095] The biological content of polymers or polymer compositions may depend on the biological content of the propiolactone used. For example, in some variations of the methods described herein, the beta-propiolactone used to produce the polymers or polymer compositions described herein may have a biological content greater than 0% and less than 100%. In certain variations of the methods described herein, the beta-propiolactone used to produce the polymers or polymer compositions described herein may
Tue a content biological at least 10%, at least 20%, fur any less 30%, fur least 40%, at least any less 50%, at minus 60%, fur minus 70%, at least 80%, fur minus 90%, fur any less 95%, fur any less 96% at least 97%, at least 98%, fur any less 99%, fur at least 99.5%, at least 99.9%, fur any less 99.99 % or 100%. In certain variations, used
beta-propiolactone derived from renewable sources. In other variations, at least part of the betapropiolactone used is derived from renewable sources and
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25/30 at least part of the beta-propiolactone is derived from non-renewable sources.
[096] The biological content of beta-propiolactone may depend, for example, on the biological content of the ethylene oxide and carbon monoxide used. In some variations, both ethylene oxide and carbon monoxide are derived from renewable sources.
[097] With reference again to FIG. 4, when ethylene oxide 402 and carbon monoxide 404 are both obtained from renewable sources, beta-propiolactone 410 is biologically based. When such a bio-based beta-propiolactone is polymerized according to the methods described herein, the resulting polymer is of the biological base. For example, with reference to FIGs. 1-3, when betapropiolactones 102, 202, and 302 are produced from renewable sources, polymers 110, 210 and 310, respectively, are bio-based polymers.
Biodegradable [098] In some variations of the previous content, the polymer or polymer composition has a biodegradability of at least 10%, at least 20%, at least 30%, at least 40%, at least 50%, at least 60% at least 70%, at least 80%, at least 90%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, at least 99.5%, at least 99.9%, at least 99.99% or 100%.
[099] In some variations of the above, biodegradable is as defined and determined based on ASTM D5338-15 (Standard Test Method for Determining Aerobic Biodegradation of Materials
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26/30
Plastics under Controlled Composting Conditions, Incorporating Thermophilic Temperatures).
Uses of Absorbent Polymers
Diapers and Other Hygiene Products [100] In other respects, absorbent articles are also provided herein which comprise the polymers or polymer compositions described herein, or produced according to the methods described herein.
[101] In some variations, the absorbent article also includes at least one inorganic or organic additive. Suitable inorganic additives can include, for example, metals (such as aluminum or tin), as well as clays. The incorporation of such solids can increase the absorbent properties of the polymer or polymer compositions. Examples of organic additives can include, for example, plasticizers such as polybutene, polypropene, polybutadiene, polyisobutene and / or polyisoprene.
[102] In some embodiments, the absorbent article is a diaper, an incontinence product for adults or a feminine hygiene product. In some variations of the above, the absorbent article is biodegradable and / or biodegradable.
[103] In certain respects, a biodegradable fabric is provided, comprising any of the polymers or polymer compositions described herein, or produced according to the methods described herein. In some variations of the above, the biodegradable fabric further comprises at least one inorganic or organic additive.
Agricultural Uses
Petition 870170103516, of 12/29/2017, p. 31/41
27/30 [104] The polymers or polymer compositions described herein, or produced according to the methods described herein, may also be suitable for agricultural use. In other respects, an agricultural product is provided which comprises the polymers or polymer compositions described herein, or produced according to the methods described herein. This agricultural product can be a material used in planting and / or growing plants, or a seed or a crop.
[105] For example, the polymers or polymer compositions described herein can be used as agricultural materials to store water for crops. Thus, in some variations, an agricultural material is provided which comprises the polymers or polymer compositions described herein. In certain variations, agricultural material also includes at least one inorganic or organic additive.
[106] In other variations, a seed coated with the polymers or polymer compositions described herein is provided. In other embodiments, a seed mixture comprising seeds is provided, in which at least part of the seeds are coated with the polymers or polymer compositions described herein. When the polymer or polymer compositions degrade biologically, water can be released.
[107] In still other aspects, a method is provided, consisting of planting seeds, in which at least part of the seeds are coated with the polymers or polymer compositions described herein. In some variations, the method also involves growing plants at
Petition 870170103516, of 12/29/2017, p. 32/41
28/30 starting from at least part of the seeds planted under conditions in which the polymers or polymer compositions degrade biologically to release water for the seeds and / or plants.
EXAMPLES [108] The following example is merely illustrative and is not intended to limit any aspect of the present invention in any way.
Example 1
Synthesis of Various Polymers and Measurement of Absorption of
Water [109] This example demonstrates the synthesis of various polymers from beta-propiolactone (bPL). The water absorption of these polymers was measured and compared with the water absorption of the commercially available superabsorbent polymer produced from acrylic acid, purchased from Aldrich.
Polymer 1: bPL + 10 mol mol NaAcr (without crosslinking agent) [110] In a flask, 4.2 mmol of sodium acrylate and 42 mmol of bPL were added and heated to 50 ° C. The reaction temperature was maintained at 50 ° C, until it was observed that all the bPL was consumed.
Polymer 2: bPL + 10 mol% NaAcr + 1 mol% ethylene carbonate [111] In a flask, 4.2 mmol of sodium acrylate were added; 0.42 mmol of aluminum acrylate as a crosslinking agent and 42 mmol of bPL and heated to 50 ° C. The reaction temperature was maintained at 50 ° C, until it was observed that all the bPL was consumed.
Polymer 3: bPL + 10 mol% NaAcr + 1 mol% acrylate
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29/30 aluminum [112] Polymer 3 was synthesized using a protocol similar to polymer 2, except that the crosslinking agent used was aluminum acrylate.
Polymer 4: bPL + 10 mol% NaAcr + 1 mol% diglycidyl ethylene glycol [113] Polymer 4 was synthesized using a protocol similar to that of polymer 2, except that the crosslinking agent used was diglycidyl ether of ethylene glycol.
Polymer 5: bPL + 10 mol% NaAcr + N, Nmethylenobis (acrylamide) [114] Polymer 5 was synthesized using a protocol similar to that of polymer 2, except that the crosslinking agent used was N, N-methylenebis (acrylamide).
Water Absorption [115] The superabsorbent polymer (SAP) purchased from Aldrich and the polymers synthesized in this Example were each tested for water absorption using blue Dextran, according to the protocols described in Fredric L. Buchholz, Journal of Chemical Education, Vol. 73, number 6, p. 512. The results of water absorption are summarized in Table 1 below.
Table 1
Sample Water Absorption (g / g) SAP (Aldrich) 134 Polymer 1 (without crosslinking agent) 14 Polymer 2 (ethylene carbonate re-titrating agent 14 Polymer 3 (reiterating agent 1
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30/30
aluminum acrylatePolymer 4 (diglycidyl ethylene glycol ether) 6 Polymer 5 (crosslinking agentN, N-methylenebis (acrylamide)) 20
Petition 870170103516, of 12/29/2017, p. 35/41
1/11
1. Method of producing a cross-linked polymer,

权利要求:
Claims (11)
[1]
CHARACTERIZED by the fact that it comprises the combination of beta-propiolactone and a crosslinker in the presence of a metal cation to produce the crosslinked polymer, in which the crosslinked polymer comprises a main structure of partially neutralized polyacrylic acid and a plurality of polypropiolactone and side chains crosslinking portions.
[2]
2. Method, according to claim
1,
CHARACTERIZED by the fact that metallic cation provided as a metallic salt.
[3]
3. Method, according to claim
2,
FEATURED by the fact that the metal is an alkali metal or an alkaline earth metal.
[4]
4. Method according to claim 2,
CHARACTERIZED by the fact that the metal is sodium or potassium.
[5]
5. Method according to the claim
2,
CHARACTERIZED by the fact that the metal cation is provided as metal acrylate.
[6]
6. Method, according to claim
5,
CHARACTERIZED by the fact that the metal acrylate sodium acrylate or potassium acrylate.
[7]
7. Method of producing a cross-linked polymer,
CHARACTERIZED by the fact that it comprises the combination of beta-propiolactone and a crosslinker to produce the crosslinked polymer, in which the crosslinked polymer comprises a main structure of partially neutralized polyacrylic acid and
2/11 a plurality of polypropiolactone side chains crosslinking portions.
[8]
8. Method according to any one of claims 1 to 7, CHARACTERIZED by the fact that the polypropiolactone side chains have, independently, a structure of the formula - (CH2CH2 (C = 0) O) nM ⁺ , in which:
n is an integer from 1 to 10 inclusive; and
M + it's a metal alkaline, a cross-linking portion or H ⁺ . 9. Methodaccording with any one of claims 1 to 8, where 0 crosslinker comprises: one compound in acrylamide,one compound in acrylate metal, one compound in organic carbonate, one compound in diglycidyl or one compound vinyl-organic comprising two or more groups vinyl, or any combination of these.
10. Method according to any one of claims 1 to 8, CHARACTERIZED by the fact that the crosslinker comprises ethylene glycol dimethacrylate, diethylene glycol diacrylate, allyl methacrylate, 1,1,1-trimethylpropane triacrylate, trialylamine or tetraalkyloxietane, or any combination of these.
11. Method according to any one of claims 1 to 8, CHARACTERIZED by the fact that the crosslinker comprises N, Ν'-methylenebis (acrylamide), aluminum acrylate, ethylene carbonate and diglycidyl ethylene glycol ether, or any combination of these .
3/11
12.
Method according to claims 1 to 8,
CHARACTERIZED crosslinker comprises a compound of
13. Method, according to the claim for silane.
Any of them
CHARACTERIZED by the fact that the silane compound has a structure of the formula Y3SiR ^a N ⁺ R ¹ R ² R ³ X, where:
Y is a hydrolyzable radical;
R ^a is a divalent hydrocarbon radical;
each of R ¹ , R ² and R ³ is independently:
a saturated or unsaturated hydrocarbon radical, or a saturated or unsaturated organic radical comprising carbon, hydrogen and at least one hetero atom
selected from of the group what It consists in oxygen, sulfur and nitrogen; and X is an anion. 14. Method, of wake up with claim 13, CHARACTERIZED BY fact of what R ^a is one radical
divalent hydrocarbon with 1 to 6 carbon atoms.
15. Method according to claim 13 or 14, CHARACTERIZED by the fact that each of R ¹ , R ² and R ³ is independently a saturated or unsaturated organic radical comprising (i) carbon, hydrogen and oxygen; (ii) carbon, hydrogen and sulfur, or (iii) or
carbon, hydrogen and nitrogen. 16. Method, of according to claim 13 or 14, CHARACTERIZED BY fact that one out of R ¹ , R ² e R ³ is regardless a radical saturated organic or
unsaturated which consists of (i) carbon, hydrogen and oxygen; (ii) carbon, hydrogen and sulfur, or (iii) or carbon, hydrogen and nitrogen.
4/11
17. Method according to any one of claims 13 to 16, CHARACTERIZED by the fact that X ^- is chloride, bromide, fluoride, iodide, acetate or tosylate.
18. Method according to any one of claims 1 to 8, CHARACTERIZED by the fact that the crosslinker comprises a polyol, a polyglycidyl ether or a combination thereof.
19. Method according to any one of claims 1 to 8, CHARACTERIZED by the fact that the crosslinker comprises a polysaccharide.
20. Method according to any one of claims 1 to 19, CHARACTERIZED by the fact that the crosslinking moieties link terminal carboxylic groups of at least a part of the polypropiolactone side chains.
21. Method according to any one of claims 1 to 20, CHARACTERIZED by the fact that the crosslinking moieties link neutralized carboxylate groups from at least part of the polypropiolactone side chains.
22. Method, in wake up with any of claims 1 to 21, CHARACTERIZED by the fact that crosslinking portions call fur least a part of main structure of acid pulley partially chronic neutralized. 23. Method, in wake up with any of claims 1 to 22, CHARACTERIZED by the fact that further comprises the combination beta-propiolactone and the crosslinker with a initiator ionic, or an initiator of
radical, or a combination of these.
5/11
24. Method, according to
CHARACTERIZED by the fact that it comprises an alkali metal salt, ionic initiator an alkaline earth metal salt or a combination of these.
25. The method of claim 23, characterized by the fact that the ionic initiator comprises an alkali metal carboxylate salt, an alkaline earth metal salt or a combination thereof.
26. Method, according to claim 23, CHARACTERIZED by the fact that the ionic initiator is an alkali metal salt.
27. Method, according to claim 23, CHARACTERIZED by the fact that the ionic initiator has a structure of the formula CH2 = CH2CC> 2 “Z ⁺ , where Z ⁺ is an alkali metal, an alkaline earth metal, ammonium, a quaternary ammonium or phosphonium cation.
28. Method according to claim 27,
CHARACTERIZED by the fact that quaternary ammonium cation is a lower alkyl quaternary ammonium cation.
29. Method, ofCHARACTERIZED BY wake up withwhat the claimthe ionic initiator 23,is fact in sodium acrylate or acrylate potassium, or an combination of these. 30. Method, of wake up with the claim 23, CHARACTERIZED BY THE FACT in that the ionic initiator is one methacrylate. 31. Method, of wake up with the claim 23, CHARACTERIZED BY fact in what the ionic initiator is
6/11 v
sodium methacrylate or potassium methacrylate, or a combination thereof.
32. Method according to any one of claims 23 to 31, CHARACTERIZED by the fact that the radical initiator comprises a peroxide, a persulfate or an azo compound, or a combination thereof.
33. The method of any one of claims 23 to 31, CHARACTERIZED by the fact that the radical initiator is a redox initiator.
34. Method according to any one of claims 23 to 31, CHARACTERIZED by the fact that the radical initiator comprises a hydroperoxide.
35. Method according to any one of claims 23 to 31, CHARACTERIZED by the fact that the radical initiator comprises hydrogen peroxide.
36. Method according to any one of claims 1 to 35, CHARACTERIZED in that it further comprises the combination of the cross-linking beta-propiolactone with an additional monomeric compound.
37. Method according to claim
36,
CHARACTERIZED by the fact that the additional monomeric compound is an organic compound comprising at least one vinyl group.
38. The method of claim 36,
CHARACTERIZED by the fact that additional monomeric compound is methacrylic acid.
39. The method of claim 36,
CHARACTERIZED by the fact that additional monomeric compound is an optionally substituted acrylic acid, or a carbohydrate, or any combination of these.
7/11 <ί
40. Method according to any one of claims 1 to 39, CHARACTERIZED by the fact that it further comprises the carbonylation of ethylene oxide to produce beta-propiolactone.
41. Method according to any one of claims 1
39, CHARACTERIZED by the fact that it also comprises a combination of ethylene oxide carbon monoxide in the presence of a carbonylation catalyst and optionally a solvent to produce beta-propiolactone.
42. Production method of a cross-linked polymer,
CHARACTERIZED by the fact that it comprises:
reacting a low molecular weight polypropiolactone with a radical polymerization initiator and a crosslinker, where the low molecular weight polypropiolactone has a formula CH ₂ = CH ₂ - (C = 0) -0- (CH2CH2 (C = 0) - 0) _n ~ M ⁺ , where n is an integer from 1 to 10 inclusive; and
M ⁺ is an alkali metal, a cross-linking portion or H ⁺ .
43. Polymer CHARACTERIZED by the fact that it is produced according to the method, as defined in any of the previous claims.
44. Polymer CHARACTERIZED by the fact that it comprises a poly (sodium acrylate / acrylic acid) backbone and a plurality of polypropiolactone side chains attached to the backbone.
45. Polymer according to claim 44,
CHARACTERIZED by the fact that the polymer is cross-linked.
46. Polymer, CHARACTERIZED by the fact that it comprises a main structure of partially polyacrylic acid
8/11 neutralized and a plurality of polypropiolactone side chains and crosslink portions.
47. Polymer according to claim 46, CHARACTERIZED by the fact that the polypropiolactone side chains have, independently, a structure of the formula - (CH2CH2 (C = 0) -0) _n ~ M ⁺ , where:
n is an integer from 1 to 10 inclusive; and
M ⁺ is an alkali metal, a cross-linking portion or H ⁺ .
48. Polymer according to any one of claims 43 to 47, CHARACTERIZED by the fact that the polymer has:
(i) a numerical average molecular weight greater than 1 million Daltons; or (ii) an average particle size between 400 and 500 pm;
or (iii) a particle size distribution of more than 70% of particles between 300 pm and 600 pm; or (iv) an extractable content of less than 20%; or (v) a residual monomer content of less than 1500 ppm;
49. Polymer according to any one of claims 43 to
48,
CHARACTERIZED by the fact that the polymer has:
(i) an absorbance under load between 10 g /
25 g / g; or (ii) an absorbance rate between 15 g and 20 g / g;
(iii) a swelling ability between
35 g / g; or
[9]
9/11 or any combination of (i) to (iii).
50. Polymer, according any an of claims 43 to 48, CHARACTERIZED by the fact that the polymer has: absorbance under load between 12 g / g and 22 g / g; and a speed absorbance between 15 g / g and 20 g / g ·51. Polymer, according any an of claims 43 to 50, CHARACTERIZED by the fact that the
polymer is bio-based, as defined by ASTM D6866.
52. Polymer, according to claim 51, CHARACTERIZED by the fact that the polymer has a bio-based content greater than 0%, but less than 100%.
53. Polymer according to claim 51, CHARACTERIZED by the fact that the polymer has a biological content of at least 20%.
54. Polymer according to any one of claims 43 to 53, CHARACTERIZED by the fact that the polymer is biodegradable, as defined by ASTM D5338-15.
55. Absorbent article, CHARACTERIZED by the fact that it comprises a polymer, as defined in any one of claims 43 to 54.
56. Absorbent article, according to claim 55, CHARACTERIZED by the fact that it also comprises at least one inorganic or organic additive.
57. Absorbent article, according to claim 55 or 56, CHARACTERIZED by the fact that the absorbent article is a diaper, an incontinence product for adults or a feminine hygiene product.
[10]
11/10
58. Absorbent article, according to any of claims 55 to 57, CHARACTERIZED by the fact that the absorbent article is biodegradable.
59. Biodegradable fabric, CHARACTERIZED by the fact that it comprises:
a polymer, as defined in any one of claims 43 to 54; and at least one inorganic or organic additive.
60. Agricultural product CHARACTERIZED by the fact that it comprises a polymer, as defined in any one of claims 43 to 54.
61. Agricultural product according to claim 60, CHARACTERIZED by the fact that the agricultural product is a material for storing water for crops.
62. Agricultural product according to claim 60, CHARACTERIZED by the fact that the agricultural product is a seed or a crop.
63. Seed CHARACTERIZED by the fact that the seed is coated with a polymer, as defined in any of claims 43 to 54.
64. Seed mixture CHARACTERIZED by the fact that it comprises a plurality of seeds, wherein at least part of the seeds is coated with a polymer, as defined in any of claims 43 to 54.
65. Method CHARACTERIZED by the fact that it comprises planting seeds, as defined in claim 63, or a seed mixture, as defined in claim 64.
[11]
11/11
66. Method according to the claim

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法律状态:
2019-04-16| B03A| Publication of a patent application or of a certificate of addition of invention [chapter 3.1 patent gazette]|

2021-02-17| B11A| Dismissal acc. art.33 of ipl - examination not requested within 36 months of filing|

2021-05-04| B11Y| Definitive dismissal - extension of time limit for request of examination expired [chapter 11.1.1 patent gazette]|

优先权:

申请号 | 申请日 | 专利标题

US201662416623P| true| 2016-11-02|2016-11-02|

US62/416,623|2016-11-02|

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