Thermoresponsive in Situ Generated Proppant Based on Liquid–Solid Transition of a Supramolecular Self-Propping Fracturing Fluid

Luo, Zhifeng; Zhang, Nanlin; Pei, Yuxin; Liu, Pingli; Li, Nianyin

doi:10.1021/acs.energyfuels.9b02501

Cited by 20 publications

(10 citation statements)

References 32 publications

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“…Proppants should withstand surrounding acid, alkali, and mineral fluids at high temperature (70–140°C) 18 . The durability of the MSDBs were evaluated by recording changes of the θ w value on their surface systematically during treated in kinds of reflux acid, alkali, and mineral solution at 110°C.…”

Section: Methodsmentioning

confidence: 99%

“…Resistance to acid, alkali, and mineralized water solution Proppants should withstand surrounding acid, alkali, and mineral fluids at high temperature (70-140 C). 18 The durability of the MSDBs were evaluated by recording changes of the θ w value on their surface systematically during treated in kinds of reflux acid, alkali, and mineral solution at 110 C. Briefly, 10 g of the MSDBs were refluxed in 200 ml of the solution for 1 month. During this period, the MSDBs were collected times and washed to neutral by distilled water.…”

Section: Durabilitymentioning

confidence: 99%

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Preparation of hydrophobic and high‐strengthpolymer microspheres based on constructing a “Functionalmonomer‐St‐DVB” copolymer structure:Ultra‐low‐densityproppants

Jinrong

Gong

Zheng

et al. 2022

J of Applied Polymer Sci

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Ultra‐low‐density proppants are of great significant in slick water fracturing system, but the polymer composite microspheres can hardly promise the quality of oil and gas due to their poor hydrophobicity. To address the issue, we prepared several types of modified styrene‐divinyl benzene copolymer microspheres (MSDBs) with long‐term durable hydrophobicity and high strength, including O‐MSDBs (hydrophobic MSDBs), LO‐MSDBs (long‐time hydrophobic MSDBs), and CO‐MSDBs (coated O‐MSDBs) on the basis of a molecular structure of “KH570‐styrene (St)‐divinyl benzene (DVB)” copolymer. In this article, the design concept and the structure of MSDBs was clarified, and performances of MSDBs are systematically discussed and compared with commercially available hydrophobic microspheres. The O‐MSDBs, a kind of nanoparticle patterned St‐DVB copolymer microspheres, were prepared by a one‐step suspension polymerization undergoing a sol–gel process, showing strong hydrophobicity with a water contact angle up to 140.7°, but short durability in strong hydrochloric acid or hydrofluoric acid; On the contrary, LO‐MSDBs perform better in the stability and durability of hydrophobicity with a slightly lower water contact angle about 135.9°. The LO‐MSDBs were designed by coating functionalized St‐DVB copolymer microspheres with fluororesin. Similarly, CO‐MSDBs from fluororesin‐coated O‐MSDBs were designed. As expected, CO‐MSDBs have a stronger hydrophobicity (139.0°) than LO‐MSDBs and longer durability than O‐MSDBs. Moreover, the MSDBs exhibit better properties than the commercially available hydrophobic polymer and ceramic microspheres.

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Section: Methodsmentioning

confidence: 99%

Section: Durabilitymentioning

confidence: 99%

Preparation of hydrophobic and high‐strengthpolymer microspheres based on constructing a “Functionalmonomer‐St‐DVB” copolymer structure:Ultra‐low‐densityproppants

Jinrong

Gong

Zheng

et al. 2022

J of Applied Polymer Sci

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“…Heavy oil has the characteristics of high viscosity and low fluidity, which causes difficulty in development with conventional approaches. Thermal enhanced oil recovery (EOR) methods have become the most popular techniques for processing heavy crude oil because of its high thermal sensitivity. , …”

Section: Introductionmentioning

confidence: 99%

Characteristics and Properties of Coke Formed by Low-Temperature Oxidation and Thermal Pyrolysis during in Situ Combustion

Luo

Lin

et al. 2020

Ind. Eng. Chem. Res.

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In order to understand the mechanism of in situ combustion, many studies have investigated the characteristics and properties of oxidized coke and pyrolyzed coke. However, in earlier research, the influence of light hydrocarbon and other compounds always led to a calculation error in the activation energy. In the work described here, we produced and separated oxidized coke and pyrolyzed coke, respectively, first to eliminate the influence of impurity and, second, to examine their properties by means of the TG-DSC equipment. The kinetic parameters were calculated by the Ozawa–Flynn–Wall model. The results showed that the crude oil achieved two major mass losses in the 300–400 and 500–600 °C temperature ranges, while the oxidized coke and the pyrolyzed coke released more heat than crude oil in the same conditions. At 300 and 350 °C, the high temperature can cause the thermal pyrolysis of the crude oil because the generation of coke requires more energy. These temperature levels cannot trigger the generation of coke and thus the pyrolyzed products stayed in one phase. At 400 °C, the pyrolyzed product cracked into two products: light oil and coke. The generated coke could only achieve major mass loss over 500 °C, releasing more heat than both oxidized oil and crude oil. According to the Ozawa–Flynn–Wall model, the crude oil achieved higher instantaneous activation energy at each conversion rate compared to results for oxidized coke and pyrolyzed coke. With the increase in conversion rate, the activation energy of oxidized coke rose while that of pyrolyzed coke decreased slightly.

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“…With the development of the global oil and gas industry, higher requirements are put forward for drilling and stimulation (Luo et al 2019). Barite, whose main constituent was barium sulfate (BaSO 4 ), was usually added into a drilling fluid as a weighting material to increase the fluid density of a drilling fluid (Elshreef and Lashin 2016;Fang et al 2018;Nguyen et al 2011;Srungavarapu et al 2018).…”

Section: Introductionmentioning

confidence: 99%

A chelating agent system for the removal of barium sulfate scale

Luo

Zhang

Wang

et al. 2020

J Petrol Explor Prod Technol

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This study aimed to prepare a chelating agent SA-20 using diethylenetriaminepentaacetic acid (DTPA) and low molecular weight sodium polyacrylate raw material for the removal of barium sulfate (BaSO 4 ) scale. The morphology of the resulting chelating agent was characterized by scanning electron microscopy. The BaSO 4 scale removal ability of SA-20 was comprehensively evaluated by the dissolving ability, particle size analysis, corrosion performance, and fracture conductivity before and after the scale removal. The results showed that the SA-20 has a good BaSO 4 scale removal ability due to the chelation, lattice distortion, and dispersion of DTPA and low molecular weight sodium polyacrylate.Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Thermoresponsive in Situ Generated Proppant Based on Liquid–Solid Transition of a Supramolecular Self-Propping Fracturing Fluid

Cited by 20 publications

References 32 publications

Preparation of hydrophobic and high‐strengthpolymer microspheres based on constructing a “Functionalmonomer‐St‐DVB” copolymer structure:Ultra‐low‐densityproppants

Preparation of hydrophobic and high‐strengthpolymer microspheres based on constructing a “Functionalmonomer‐St‐DVB” copolymer structure:Ultra‐low‐densityproppants

Characteristics and Properties of Coke Formed by Low-Temperature Oxidation and Thermal Pyrolysis during in Situ Combustion

A chelating agent system for the removal of barium sulfate scale

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