Self-emulsifiable soybean oil phosphate ester polyols for low-VOC corrosion resistant coatings

Guo, Yinzhong; Mannari, Vijay; Patel, Pulin; Massingill, John L.

doi:10.1007/s11998-006-0030-5

Cited by 18 publications

(18 citation statements)

References 11 publications

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“…Phosphoric acid plays an important role in the formation of phosphate esters. Phosphoric acid (o-H 3 PO 4 ) has been extensively used in the preparation of a series of soybean oil phosphate esters for rigid polyurethanes, coatings, surfactants and anti-wear additives (Dwan'Isa et al, 2003;Guo et al, 2007;Guo et al, 2006;Zhong et al, 2001). Soy-based polyols having tunable hydroxyl content and phosphate ester functionality are possible by controlling the type and amount of polar solvent and phosphoric acid content added to the reactants (Guo et al, 2007).…”

Section: Chemical Routesmentioning

confidence: 99%

“…Much of the work done to produce soybean oil phosphate ester polyols used water and significant amount of polar solvents such as 2-propyl alcohol, methanol, to obtain high hydroxyl functionality while keeping the final acid values low (Guo et al, 2007;Guo et al, 2006;Mannari and Massingill, 2006;Lin et al, 2008 Another oxirane ring cleavage process that results to a higher molecular weight polyol and high hydroxyl functionality is the batch reaction of ESBO and ethylene glycol (EG) at temperatures greater than 200 °C and ethylene glycol concentration range of 2-9%. An optimal condition will obtain a product with complete incorporation of ethylene glycol in ESBO and decreased oxirane concentration in the final product which is characterized by homogeneity, high viscosity and low acid number (Lubguban et al, 2009).…”

Section: Chemical Routesmentioning

confidence: 99%

“…The objective is to increase the average hydroxyl equivalent weight of the soybean oil to engage much of the mass of the crosslinked soy-based polyol complex while reacting its hydroxyl groups with the reactive -NCO groups of the isocyanates. Examples of high hydroxyl equivalent weight soy-based polyols are glycerolized bodied soybean oil, glycolysis oligomers, and soy phosphate esters (Lubguban, et al, 2009;Guo et al, 2006).…”

Section: Increasing Reactivity and Hydroxyl Equivalentmentioning

confidence: 99%

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Soy-Based Polyols and Polyurethanes

Lubguban

Ruda

Aquiatan

et al. 2017

KIMIKA

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Polymers derived from plant oils have attracted major commercial interest and significant attention in scientific research because of the availability, biodegradability, and unique properties of triglycerides. Triglycerides rich in unsaturated fatty acids, such as soybean oil (SBO), are particularly susceptible to chemical modification for desired polymeric materials. Soy-based polyols are important industrial prepolymeric materials that use renewable resources; and can be produced or derived through different processing routes. This review paper discusses previous and recent researches about chemical and biochemical polymerization processes to produce soy-based polyols as prepolymers for the production of polyurethane materials in the form of foams (rigid or flexible) and elastomers. The central goal of these research fields is to find effective reaction routes to increase both equivalent weight and hydroxyl functionality of soy-based polyols while taking into consideration the simplicity and economics of these processes.

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Section: Chemical Routesmentioning

confidence: 99%

Section: Chemical Routesmentioning

confidence: 99%

Section: Increasing Reactivity and Hydroxyl Equivalentmentioning

confidence: 99%

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Soy-Based Polyols and Polyurethanes

Lubguban

Ruda

Aquiatan

et al. 2017

KIMIKA

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“…Our research group has focused on developing a platform of polymer building blocks derived from soybean oil for coatings and related applications (7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19). Polymeric and oligomeric materials used for UV-cure systems must meet stringent requirements of functionality, reactivity, viscosity, thermo-mechanical properties of their films, and cost for their successful deployment as film formers (20).…”

Section: Introductionmentioning

confidence: 99%

Soy-Based Building Blocks for Advanced Photocure Coating Systems

Mannari

Patel

et al. 2015

ACS Symposium Series

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Phone: +1 734-487-1235.Photocuring technology is among the fastest-growing advanced coating technologies primarily due to their sustainability features, potential for enabling new products, and economy. Despite these benefits, the materials used in the current photocure systems are predominantly derived from petrochemical sources, making them unsustainable over the long term. Development of renewable resource-based alternate materials tailored for photocure applications is, therefore, critical to future sustainable development of photocure coating technology.This presentation highlights our research efforts in developing a platform of soybean oil-based value-added building blocks and demonstration of their suitability as alternative raw materials in advanced UV-curing coating compositions. A hyper-branched soy urethane acrylate (HSPU) has been developed and used as the primary component of UV-curable composition. Coatings based on HSPU with varying acrylate content (using reactive diluent) and high bio-based content have been characterized and compared. Due to hyperbranched structure and large free volume in their inherent structure, they exhibited interesting properties for many potential industrial applications. Another group of soy-based derivatives-low viscosity and high-functionality acrylate monomers-have been designed and used as reactive diluent in UV-cure formulation. The study demonstrates potential of these low odor and bio-based reactive diluents as partial or full replacement of conventional reactive diluents.

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“…[7] Soybean oil phosphate ester polyols have been evaluated in low-VOC corrosion resistant coatings. [8] U.S. Pat. No.…”

Section: Introductionmentioning

confidence: 99%

Emulsion Copolymerization of Vegetable Oil Macromonomers Possessing both Acrylic and Allylic Functionalities

Kaya

Mendon

Delatte

et al. 2013

Macromolecular Symposia

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Summary: A soybean oil-based vegetable oil macromonomer (VOMM) was incorporated as a comonomer into an all-acrylic copolymer via semi-continuous emulsion polymerization. Structurally, VOMMs are comprised of long hydrocarbon fatty acid moieties with allylic double bonds which enable auto-oxidative crosslinking at ambient temperature. VOMMs facilitate low temperature film formation and the fatty acid chains tethered to the polymer backbone auto-oxidize upon film formation to yield crosslinked films. Latexes with varying VOMM levels were synthesized to elucidate the effect of VOMMs on the pre-cure and post-cure glass transition temperature (T g ) and minimum film formation temperature (MFT). Thermoplastic control latexes (without VOMM) were also synthesized via copolymerization of butyl acrylate and methyl methacrylate. This paper details the characterization performed to validate and quantify the VOMM allylic unsaturation retention before, during, and after polymerization, and to quantify and confirm the increase in T g resulting from auto-oxidative crosslinking via solid state 13 C nuclear magnetic resonance spectroscopy and differential scanning calorimetry.

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Self-emulsifiable soybean oil phosphate ester polyols for low-VOC corrosion resistant coatings

Cited by 18 publications

References 11 publications

Soy-Based Polyols and Polyurethanes

Soy-Based Polyols and Polyurethanes

Soy-Based Building Blocks for Advanced Photocure Coating Systems

Emulsion Copolymerization of Vegetable Oil Macromonomers Possessing both Acrylic and Allylic Functionalities

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