Patent Application
20100062668
This application is based upon U.S. patent application Ser. No. 11/655,601, entitled “Emulsion Polymer Binder with Aziridine Crosslinking Agent for Glass Fiber Webs”, filed on Jan. 19, 2007. The priority of U.S. patent application Ser. No. 11/655,601 is hereby claimed and its disclosure incorporated herein by reference.
The present invention relates generically to polymeric binder compositions for mineral fiber mats, and more particularly to carboxylated emulsion binder compositions that are crosslinked with a polyfunctional aziridine compound and are substantially formaldehyde free.
Fiberglass and other mineral fiber based products are used as insulation for homes, automobiles, appliances, pipes, ducts and the like. Fiberglass mats are generally produced by bonding a web of glass fibers with a polymeric binder that crosslinks when heated. The polymeric binder enables the glass fibers to adhere to one another and provides strength to the fiberglass mat while allowing it to remain somewhat flexible.
Conventionally, a phenol-formaldehyde polymer was used as the binder in fiberglass or other mineral fiber insulation products. Recently, however, formaldehyde-free binder systems have been developed due to health concerns about formaldehyde emissions in products containing the phenol-formaldehyde resin. Conventional formaldehyde-free binder compositions for glass fibers typically include a polycarboxylic acid, a hydroxyl functional compound, and a curing agent. For example, U.S. Pat. No. 6,331,350 to Taylor et al. describes a formaldehyde-free binder for fiberglass mats which comprises homopolymers or copolymers of carboxylic acids, a polyol compound, and a phosphorous containing accelerator agent. The Taylor et al. reference states that it is critical for the pH of the binder to be below about 3.
U.S. Pat. No. 7,067,579 to Taylor et al. describes a similar polycarboxy/polyol binder composition for fiberglass, where the total ratio of hydroxyl groups to carboxylic acid groups is in the range of from about 0.6:1 to 0.8:1. See also, United States Patent Publication Number 2006/0079629 to Taylor et al.
U.S. Pat. No. 5,977,232 to Arkens et al. relates to a crosslinkable binder for glass fibers which comprises a carboxylic acid polymer, an active hydrogen compound such as polyols, polyvinyl alcohol, or acrylate resins, and a fluoroborate accelerator agent.
United States Patent Application Publication No. 2005/0059770 to Srinivasan et al. teaches a formaldehyde free binder for fiberglass which includes a polymer with carboxylic acid monomer units and hydroxyl monomer units, and a crosslinking agent which promotes esterification between the carboxylic moieties and the hydroxyl moieties.
Another approach to formaldehyde-free systems is described in United States Patent Application Publication No. 2006/0258248 to Shooshtari et al. which discloses a fiberglass binder composition that includes a multifunctional carboxylic acid or anhydride, epoxidized oils, and optionally, a crosslinking catalyst such as imidazole or tertiary amines.
A particularly significant formaldehyde free binder system is described in U.S. Pat. No. 6,884,849 to Chen et al. The Chen et al. reference relates to a formaldehyde free binder composition for glass fibers, where the binder includes a polyvinyl alcohol based resin, a low molecular weight polycarboxylic acid polymer, and a sodium hypophosphite accelerator. Exemplary compositions described in Chen et al. include a binder that is a 1:1 mixture of polyvinyl alcohol resin and maleic acid. The binder described in Chen et al. is used by Owens-Corning to produce formaldehyde free fiberglass webs.
While these approaches provide binders with substantially reduced formaldehyde emissions as compared to conventional phenol-formaldehyde binder resins, the above binder systems are cost prohibitive because they require large amounts of expensive components in order to achieve sufficient crosslinking density. For example, the Chen et al. reference described above requires a composition of 50 weight percent of maleic anhydride—a high quantity of the more expensive component. Additionally, the prior art binder compositions generally require high curing temperatures (350° F. or more) which adds additional expense to the system.
Other formaldehyde free crosslinking systems have been used in fields such as cellulosic coatings. For example, triaziridine compounds have been used to crosslink carboxylic acid functionalized polymer binders in cellulosic fabrics. U.S. Pat. No. 6,117,492 to Goldstein et al. relates to formaldehyde-free emulsion binder compositions for nonwoven webs that are adapted to crosslink at low temperatures. The emulsion polymers include acetoacetoxy moieties and carboxylic acid moieties, and are combined with a polyaldehyde crosslinking agent and a polyaziridine crosslinking agent.
U.S. Pat. No. 6,506,696 to Goldstein et al. discloses binder compositions for synthetic nonwoven webs where the binder compositions include a polymer with carboxylic acid functionality and acetoacetate functionality. The binder composition is crosslinked with both aziridine compounds and dialdehyde compounds.
Likewise, U.S. Pat. No. 6,426,121 to Goldstein et al. discloses a low temperature crosslinking binder composition for nonwoven webs, where the binder composition includes an emulsion polymer with carboxylic acid functionality and is stabilized with polyvinyl alcohol protective colloids. The binder in Goldstein et al. is crosslinked with both a polyaldehyde compound and a polyaziridine compound.
Binders used in cellulosics or thermoplastic webs are generally substantially different from those used in glass fiber substrates because glass fibers do not have reactive functional groups like cellulose fibers (—OH) or thermoplastic fibers (if treated, —OH). The cellulosic binders described in the above references generally contain difunctional crosslinking systems, which include a hydroxyl functional crosslinker to create crosslinked groups between the functional group on the fiber and the functional group on the binder. See, e.g., the '121 Goldstein et al. reference at col. 6, lines 17-24, and col. 7, lines 49-64. Additionally, the above-described binders which are crosslinked with triazidines have low glass transition temperatures, which are generally not suitable for manufacturing fiberglass insulation products because it causes the fiberglass web to block when it is wound onto a roll.
The present invention provides cost-effective formaldehyde free binder compositions for mineral fibers such as fiberglass, where the binder compositions exhibit comparable or improved strength and flexibility properties as compared to conventional binder systems. According to one embodiment of the invention, the binder composition is derived from crosslinking a polymer which has 0.05 to 50 weight percent of carboxylic acid units (based on total monomer weight), with a polyfunctional aziridine crosslinking agent.
Further features and advantages of the present invention will become apparent from the discussion that follows.
The present invention is described in detail below with reference to the various examples. Modifications to particular examples within the spirit and scope of the present invention, set forth in the appended claims, will be readily apparent to those of skill in the art.
Unless otherwise indicated, terms are to be construed in accordance with their ordinary meaning. Percent, for example, refers to weight percent, unless context indicates otherwise. Following are some exemplary definitions of terms used in this specification and the appended claims.
“Parts per hundred weight resin,” or “pphr” is defined herein as the weight of a component per 100 units weight of the polymer dispersion solids, i.e., actives on actives.
“Film insolubles” relates to the crosslinking properties of a binder composition and is measured as described in the examples below. That is, an approximately 6 mil film is formed by pouring the binder composition into a mold, air drying for about 16 hours, and thermally curing it for the time and temperature specified. A sample of the film is then refluxed in the specified solvent for 2 hours, the solvent is evaporated, and the residual weight is measured and used to calculate the percent film insolubles. The film insolubles level of a composition generally correlates to the crosslinking ability of the binder, i.e., higher film insolubles indicates greater crosslinking density.
“Mineral fibers” and like terminology means and includes fibers made from minerals or metal oxides such as fiberglass, rock wool, ceramic fibers and the like whether naturally occurring or synthetic. These materials are typically in the form of a mat or web prior to application of the binder and may be used in connection with insulation and fiber mats/tissues/veils for flooring and roofing applications.
The mineral fiber binder composition of the invention includes a carboxylic acid functional polymer which is crosslinked with a polyfunctional aziridine agent. The carboxylic acid polymers used in the invention are generally emulsion polymerized resins which include carboxylic acid monomer units that are incorporated into the backbone of the polymer. The carboxylic acid moieties on the polymer react with the aziridine crosslinking agent to provide a durable binder composition. The binder polymer may include from 0.05 to 50 weight percent acid units and preferably from 0.1 to 10 weight percent acid units, based on total monomer weight. Other suitable ranges for the carboxylic acid monomer amounts include from 0.25 to 5 weight percent acid units, and from 0.25 wt. percent to 2 weight percent.
The choice of carboxylic acid monomers is not particularly limited and may include one or more monomers such as acrylic acid, methacrylic acid, crotonic acid, itaconic acid, and monoesters of dicarboxylic acids such as monoethyl maleate. Dicarboxylic acids are also suitable, including maleic acid, fumaric acid, and aconitic acid. Additionally, for the purposes of this invention, anhydrides of carboxylic acids may be used as the carboxylic acid monomer; an exemplary anhydride is maleic anhydride.
The binder polymer used in the invention includes a minor portion of carboxylic acid monomer units. The balance of ethylenically unsaturated monomer units in the binder resin is not particularly limited, and may include vinyl-based monomers including vinyl esters such as vinyl acetate, vinyl ethylene carbonate, vinyl 2-ethylhexanoate, and vinyl versatate; vinyl halides such as vinyl chloride and vinylidene chloride; vinyl benzoate, and N-vinyl formamide; (meth) acrylic monomer units such as butyl acrylate and methyl methacrylate; styrenic monomer units; dienes such as butadiene; alpha olefins including ethylene and propylene; and any combinations of the preceding.
Typically, the carboxylated emulsion polymer includes resins such as vinyl acetate polymers, vinyl acetate-ethylene polymers, and styrene-butadiene polymers. The use of vinyl acetate based polymers is preferred. Preferably, the emulsion polymer includes at least 50 weight percent vinyl acetate monomer units, and even more preferably at least 90 weight percent.
Additionally, while the polymer is reacted with an aziridine post-crosslinking agent to create crosslinking moieties, it may be desirable to include a small amount (0.05 to 0.5 wt. percent, based on total monomer weight) of polymerizable precrosslinking monomer units in the binder polymer. Suitable precrosslinking monomers include diallyl phthalate, tiriallyl cyanurate, hexamethylene diacrylate or the like.
In a particularly preferred embodiment of the invention, the binder polymer includes from 0.5 to 5 weight percent of carboxylic acid monomer units, and from 95 to 99.5 weight percent of vinyl acetate monomer units, based on the total monomer weight.
The binder polymer used in the invention is generally emulsion polymerized in an aqueous medium in the presence of stabilizing agents such as emulsifiers, surfactants, protective colloids, or combinations thereof.
It is known that the polyfunctional aziridine crosslinking agents may also form crosslinking moieties with hydroxyl functional components, which are present, for example, in polyvinyl alcohol (PVOH) protective colloids. In preferred embodiments of the invention, however, the binder polymer is substantially free of polyvinyl alcohol protective colloids, i.e., less than about 0.3 pphr. The presence of PVOH colloids increases the viscosity of the emulsion, thus requiring a low-solids product, or requiring dilution prior to application to the fibers. Additionally, it has been discovered in connection with the present invention, that the presence of hydroxyl-functional colloids may actually reduce the overall crosslinking effectiveness because the aziridine crosslinking agent is reacting with ungrafted components.
The use of surfactant-only stabilized resins in the invention enables the production of high solids emulsions which is desirable from a cost perspective. The emulsions may be prepared at a solids content of from about 25 to about 70 weight percent, and more typically from about 40 to 60 weight percent. The binder resin is usually applied to the glass or mineral fibers in aqueous emulsion form; however, the polymer may be added to the fibers in any form which is suitable to the particular manufacturing process used. The surfactant-stabilizing system used in some embodiments of the invention may be substantially free of alkylphenol ethoxylate (APE) surfactants. APE-type surfactants are suspected of being linked to human health issues, and in particular are discouraged or banned in European markets.
The polymer component in the binder of the invention may have a higher glass transition temperature than conventional resins used with aziridine crosslinkers. Low glass transition temperature resins are not preferred for use as a binder in fiberglass insulation, because the bonded fiberglass mats are wound onto rolls while the mat is still warm. Accordingly, if the binder composition is excessively tacky, the fiberglass roll will block and the layers in the roll will adhere to each other. Generally, the emulsion polymer in the invention has a glass transition temperature of at least 20° C., and more preferably at least 35° C. A suitable range of glass transition temperatures is from 25° C. to 100° C. For example, polyvinyl acetate polymers usually have a Tg in the range of from about 28° C. to about 40° C. It may be preferable to use an even higher glass transition temperature which may be accomplished by, for example, copolymerizing vinyl acetate with higher Tg monomers such as vinyl versatate (particularly VeoVa 9), vinyl benzoate, N-vinyl formamide, methyl methacrylate, vinyl ethylene carbonate or other higher Tg monomers. Binder polymers with glass transition temperatures of from 40° C. to 80° C. or from 50° C-75° C. may be preferred in some processes. In any event, if used in fiberglass insulation applications, the cured binder composition should be substantially block resistant.
The aziridine post-crosslinking agent which is included in the binder composition of the invention is operative to form crosslinking moieties between carboxylic acid groups on the binder polymer, thus making the resin more durable. The post-crosslinking agent, is generally added to the aqueous binder composition prior to applying the composition to the glass or mineral fiber mat. The crosslinking reaction initiates when the composition dries, either by air-drying or heating. Where vinyl acetate based polymers are used, the aziridine crosslinking agent is typically added to the binder polymer within 4 hours prior to application of the binder to the glass fibers because the activity of the aziridine agent is degraded over time in the presence of water.
The polyfunctional aziridine crosslinking agents have at least two aziridine functional groups, and preferably have at least three aziridine functional groups. The aziridine functional groups have the following general structure, or are derived therefrom:
In the above formula, one or both of the CH2 moieties on the aziridine functional group may be substituted, for example, with methyl or alkyl groups.
A variety of polyfunctional aziridine compounds are suitable to crosslink the carboxylic acid moieties in the inventive binders. Typically, the aziridine compounds include from 3 to 5 nitrogen atoms per molecule. Examples include N-(aminoalkyl) aziridines such as N-aminoethyl-N-aziridilethylamine, N,N-bis-2-aminopropyl-N-aziridilethylamine, and N-3,6,9-triazanonylaziridine.
Preferred crosslinking agents include bis and tris aziridines of di and tri acrylates of alkoxylated polyols, including the trisaziridine of the triacrylate of the adduct of glycerine and propylene oxide; the tris aziridine of the triacrylate of the adduct of trimethylolpropone and ethylene oxide; and the tris aziridine of the triacrylate of the adduct of pentaerythritol and propylene oxide. Especially preferred polyfunctional aziridine crosslinking agents are the triazirdine compounds with structures corresponding to I and II, below:
Crosslinking agents with the above formulas are commercially available as NEOCRYL CX-100® from DSM (structure I), and as XAMA 7® from Bayer Material Science (structure II). Additional polyfunctional aziridine compounds are disclosed in U.S. Pat. No. 4,278,578 to Carpenter, and U.S. Pat. No. 4,605,698 to Briden, the entireties of which are incorporated herein by reference.
It has been discovered according to the present invention that the trisaziridine crosslinking agent performs best in conjunction with carboxylic acid functional groups, and that difunctional crosslinking activity is not needed to achieve good crosslinking properties. Accordingly, unlike prior art composition the binder polymer of the invention does not require hydroxyl functional compounds such as polyols, nor does it need hydroxyl crosslinking agents such as polyaldehydes. In this regard, it is noted that difunctional hydroxyl crosslinking agents (e.g. glyoxal) are added in cellulosic or synthetic thermoplastic webs to provide crosslinking moieties between the substrate and the binder polymer to provide water resistance to the web. For example, glyoxal will react with hydroxyl groups on the cellulose web or synthetic web (if corona treated) and any hydroxyl groups in the binder. The glass and mineral fiber substrates that are the focus of the present invention, in contrast, generally do not have hydroxyl functional groups on the fibers. Accordingly, the presence of hydroxyl crosslinking agents only adds to the overall cost of the system without enhancing performance of the binder. Preferably, the binder polymer used in the invention is substantially free of polyaldehyde crosslinking agents, e.g., less than about 0.3 pphr.
In addition to the necessary components of the crosslinked binder composition of the invention discussed above, the binder compositions may also optionally contain various additives such as plasticizers, biocides, fillers, thickening agents, detackifying agents, anti-foaming agents, UV stabilizers, lubricants, release agents, pigments, opacifiers, dyes, as well as any other known additives in the polymer arts.
As mentioned, the polymers are generally prepared and applied as emulsions. While emulsion resins are typically prepared in an acidic aqueous environment (pH of less than about 4), it has been discovered in connection with the present invention that if the pH of the emulsion is raised prior to adding the aziridine crosslinking agent, the binder exhibits improved stability. For instance, when the crosslinking agent is added to a very acidic emulsion polymer, the composition becomes rubbery over a time period of a few hours or so. Suitably, the pH of the binder composition is raised to between 5 and 9 and more preferably to between 6.5 and 8.5. Surprisingly, raising the pH of the binder composition also appears to improve the crosslinking ability of the composition.
To prepare the fiberglass insulation material, matted glass fibers are bonded together by a cured polymeric material. Generally, molten streams of glass are drawn into fibers of random lengths and blown into a forming chamber where they are randomly deposited as a mat onto a traveling conveyor. Other fibers may also be incorporated into the mat such as cellulose fibers, cellulose derivatives, thermoplastic fibers, or the like. Additionally, other components such as mineral fillers may be incorporated into the mat. The polymeric binder composition may be applied to the fibers while they are in transit to the forming chamber and while still hot from the drawing operation. The binder composition is typically applied by spraying.
The residual heat from the glass fibers and the flow of air through the fibrous mat during the forming operation volatilizes some of the water from the binder, thereby leaving the remaining components of the binder on the fibers as a viscous or semi-viscous high solids liquid. The polymer binder tends to accumulate at the junctions where fibers cross each other; to hold the fibers together at these points. The coated fibrous mat is transferred to a curing oven where heated air is blown through the mat to cure the binder and rigidly bond the glass fibers together. Alternatively, the coated fibrous mat may be allowed to air dry. After the binder composition is cured, the bonded webs are immediately transferred to rolls.
Other methods of making fiberglass mats are suitable as well. The fiber mats may also be formed by wet-laid processes where the glass fibers are slurried in water, and the web is formed by dewatering the slurry. In processes such as these, the emulsion binders may be added to the glass fibers after the web is dewatered.
Methods of making bonded fiberglass mats are well known in the art, and any suitable technique may be used in connection with the present invention. Various processes for making fiberglass mats are described in U.S. Pat. No. 5,614,132 to Bakhshi et al., U.S. Pat. No. 5,883,020 to Bargo et al., U.S. Pat. No. 6,923,883 to Kissell et al., United States Patent Application Publication No. 2006/0019024 to Freeman et al., and United States Patent Application Publication No. 2006/0009569 to Charbonneau et al., the entireties of which are incorporated herein by reference.
The bonded fiberglass webs made according to the invention are useful in thermal insulation and acoustic insulation applications, and also may be formed into a fabric that is heat resistant and corrosion resistant.
The following examples are presented to further illustrate and explain the present invention and should not be taken as limiting in any regard.
In the following examples, the crosslinking ability of different binder compositions was evaluated by measuring the film insolubles level of films cast from the polymer compositions. To measure film insolubles, the binder samples are poured into molds which are sized to produce dried films having a thickness of approximately 6 mil. The mixture is allowed to air dry (approx. 20° C.) for approximately 16 hours. The dried film is then cured at the specified time and temperature. A sample of the film (approx. 0.5 g) is weighted and placed in an Erlenmeyer flask. 100 ml of solvent (usually dimethyl formamide, acetone, or toluene) is added via a volumetric flask and the film is refluxed for two (2) hours. The solvent is then cooled and filtered through Whatman #4 Qualitative Filter Paper. Using volumetric pipettes, 10 ml of the solute is added to a tared aluminum pan (done in duplicate). The solvent is then evaporated in an oven and the pan is re-weighed to determine the residue weight (solubilized portion of the polymer). The percent insolubles is calculated as follows (averages used as applicable):
High insolubles content indicates a higher crosslinking density.
The following comparative binder system was measured for film insolubles in dimethyl formamide. The polymer in the following example represents the formaldehyde free binder system developed by Owens-Corning, and is a widely used formaldehyde free binder formulation for glass fibers.
As can be seen, the Owens Corning binder exhibits very good crosslinking density. However, the use of 50 weight percent of maleic acid is undesirable from a cost perspective, as it is by far the most expensive component in that binder system. A cheaper, formaldehyde-free binder system with comparative crosslinking ability to polymer A is needed.
Carboxylated Emulsion Resins with Crosslinking Agents
In the following examples, the effect of using various crosslinking agents on carboxylated binder resins was measured. The aqueous latexes were measured for insolubles at a pH of about 4.5 in the presence of various crosslinking agents, and also without crosslinkers. The following crosslinking agents are used in these examples:
The latex components used in the following examples are outlined below:
The polymers in the examples were dispersed in water and, where applicable, a crosslinking additive was added to the aqueous composition in the weight percent listed (based on the polymer solids). The compositions were then poured into film moldings, dried, cured, and then tested for film insolubles, as described in greater detail above.
The data for polymers B and C illustrate that the polyfunctional aziridine crosslinking agent is effective to significantly improve the crosslink density of the carboxylated polymers. The aziridine groups in the crosslinking agent react with the pendant acid moieties on the polymer to form crosslinking groups between adjacent polymer chains. The effectiveness of the aziridine crosslinking agent, as compared to other crosslinking agents, is evident from the following tests of polymer D and polymer E.
As can be seen above, the polyfunctional aziridine crosslinking agents are effective to substantially improve the crosslinking density of carboxylated emulsion polymers, even when used in relatively small amounts. Significantly, the use of non-aziridine crosslinkers provide binder compositions which exhibited substantially lower crosslinking densities than resins which were crosslinked with aziridine functional compounds. For example, even when used in amounts of 10 percent, epoxy based and isocyanate based crosslinkers did not achieve a crosslinking density that was even comparable to that achieved by using only 2.5 percent of the aziridine compound. In this regard, the superiority of the aziridine crosslinked system is clear.
It is also interesting to note that polymer D, which is stabilized with polyvinyl alcohol, exhibits slightly inferior crosslinking ability to polymer E which is surfactant stabilized. For example, at 2.5% crosslinker polymer D exhibits enhanced insolubles by about 78% while polymer E exhibits an increase in insolubles of about 85%. Without intending to be bound by theory it is believed that the PVOH interferes somewhat with the carboxylic acid/aziridine reaction, as the hydroxyl group is also reactive with aziridines. Most of the PVOH is not grafted, and thus, reaction between ungrafted chains, or even between a grafted group and an ungrafted group does not provide a comparable level of crosslinking density. The results of polymer D are, however, still considered good.
Still, the use of PVOH stabilized systems are not preferred for most applications (even if used with a carboxylated resin) because emulsion resins which are stabilized with PVOH colloids have a higher viscosity than similar surfactant-stabilized systems, and may require dilution to make them more processable.
Comparative Data: Non-Carboxylated Binder Systems Stabilized with PVOH
In the following comparative examples, non-carboxylated polymers stabilized with polyvinyl alcohol protective colloids were crosslinked with a polyaziridine functional crosslinking agent and tested for film insolubles. These polymers do not contain carboxylic acid units. The hydroxyl groups on the polyvinyl alcohol stabilizer react with the additive to form crosslinking moieties. The first set is tested for insolubles in acetone and the second in DMF.
The polymers in the examples were dispersed in water and, where applicable, a crosslinking additive was added to the aqueous composition in the weight percent listed (based on the polymer solids). The compositions were then poured into film moldings, dried, cured, and then tested for film insolubles, as above.
In the first table, the insolubles data for polymer F is artificially high because the PVOH renders the polymer somewhat insoluble in acetone, even without crosslinking moieties. Without any additive, for instance, the polymer had an insolubles content of 60.2%. The addition of crosslinker did not impart significant improvements to the binder. The effect of aziridine crosslinker on non-carboxylated resins is more clearly seen with respect to Polymer G which was tested in a stronger solvent and has a similar composition to polymer F. The presence of aziridine crosslinking agent provided only a small improvement in film insolubles content.
Compare polymers G and F with polymer E above. The presence of aziridine in polymer F (uncarboxylated) provided an increase in film insolubles of about 15-20 percent (absolute increase, i.e., 74.9%-60.2% equals an absolute increase of 14.7 percent). The presence of aziridine in polymer G, which is also not carboxylated, was effective to increase the insolubles content by only one or two percent, Polymer E (carboxylated), in contrast, exhibited an increase in film insolubles of 80 percent or more with the addition of aziridine crosslinking agent. Furthermore, even modest improvements in the non-carboxylated binders required significant amounts of crosslinking agent, which increases the overall expense of the system. The presence of carboxylic acid groups in the binder polymer is, therefore, crucial to the operability of the present invention.
Carboxylated Vinyl Acetate Based Binders with Aziridine Crosslinker
In the following examples, various vinyl acetate based polymers were treated at a pH of 6 with the polyfunctional aziridine crosslinking agent (NeoCryl CX-100), and measured for film insolubles in DMF. The latexes used have the following components.
The polymer binder compositions were prepared as described above, and tested for film insolubles.
The above data demonstrates that formaldehyde free binder compositions can be fabricated which exhibit comparable crosslinking properties to prior art technology at a fraction of the cost. Compare, for example, latex A (Owens-Corning), with latex L or M of the invention. Similar crosslinking densities are achieved using only 0.5 wt. % of the more expensive carboxylic acid component, as opposed to 50 wt. % carboxylic acid as is required in the formulation of comparative latex A.
In the following examples, a carboxylated styrene-butadiene latex and a carboxylated vinyl acetate-ethylene polymer were tested for crosslinking properties using the CX-100 trisaziridine crosslinking agent. The following emulsions were used in the examples.
The polymer binder compositions were prepared as described above, and tested for film insolubles.
The insolubles content in the SBR is somewhat inflated in the above data because SBR is inherently insoluble in most solvents (note the insolubles content without crosslinkers); however, the use of the trisaziridine crosslinking agent did improve the insolubles as compared to an SBR rubber without crosslinking agent. Moreover, it was observed in the above examples that the SBR which was reacted with aziridine crosslinking agents had markedly less surface tackiness than the SBR polymer which was not reacted with aziridine additive. Thus, the use of the polyfunctional aziridine compound may enable the use of a carboxylated SBR binder system that would otherwise be infeasible due to excessive blocking of the tacky polymer. The use of SBR systems would be highly desirable because they are extremely cost competitive.
The invention may also be used with carboxylated VAE resins which exhibited good crosslinking density. Accordingly, the aziridine crosslinking system is useful in connection with a wide variety of carboxylated polymers.
In the following examples the effect of the pH of the aqueous binder composition on the crosslinking density was measured. In the following examples, the samples with a pH of 7.7 were prepared by adding ammonium hydroxide to the aqueous emulsion prior to addition of the crosslinking agent, until the desired pH was reached.
The latex in the following examples is the same formulation used in latex C above, which is a surfactant stabilized vinyl acetate polymer with 0.5 wt. % acrylic acid (same as above).
Surprisingly, raising the pH of the emulsion resins resulted in a significantly higher crosslinking density than using the more acidic latex, even when air-dried. Additionally, it had previously been observed that when crosslinking agents were added to the acidic latex, the composition became rubbery over time, and made the emulsion difficult to process. This problem was not experienced when the pH of the latex was raised.
In view of the foregoing discussion, relevant knowledge in the art and references discussed above in connection with the Background and Detailed Description, the disclosures of which are all incorporated herein by reference, further description is deemed unnecessary.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US07/25915 | 12/18/2007 | WO | 00 | 7/15/2009 |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 11655601 | Jan 2007 | US |
| Child | 12448925 | US |
