Oluwatoyin Joseph Gbadeyan, Bruce Sithole, Sarp Adali, Glen Bright
{"title":"超质量对撞机制备蜗牛壳纳米碳酸钙工艺优化","authors":"Oluwatoyin Joseph Gbadeyan, Bruce Sithole, Sarp Adali, Glen Bright","doi":"10.1080/02726351.2023.2274903","DOIUrl":null,"url":null,"abstract":"AbstractThis study uses the optimal (custom) design to focus on the supermasscolloider wet milling process for synthesizing calcium carbonate nanoparticles from the Achatina Fulica using the optimal (custom) design. The snail shell particle size of 150 μm from dry milling was wet milled to get smaller particle sizes. The response surface design method was used to investigate the effect of independent parameters such as consistency (amount of microparticle loading in calcium carbonate suspension) and the number of runs on the particle size of calcium carbonate produced using a supermasscolloider. Results show that the microparticle loading in calcium carbonate suspension and the number of runs significantly affected the synthesized particles. The increase in microparticle loading reduced the effectiveness of the supermasscolloider blade, resulting in the production of particle sizes ranging from 21- to 40 nm. A higher number of runs with a smaller loading of microparticles in calcium carbonate suspension offered a fine particle size of 21.30 nm. The experimental data quartic polynomial models gave a coefficient of determination (R2) of 0.92. The optimum milling runs of 750 and 1% consistency microparticle loading produced a calcium carbonate nanoparticle size of 21 nm. This technique has shown that calcium carbonate nanoparticles can be produced at low cost, at less period, with low agglomeration from Achatina Fulica shell using supermasscolloider.Keywords: Achatina fulica shellparticle sizenano-CaCo3supermasscolloidermilling processdesign expect AcknowledgmentsThe authors want to acknowledge the University of KwaZulu-Natal, where this research was conducted and that the abstract presented at PolyScience2022, having the same title as this manuscript, is entirely different from the result reported in this study. The study presented was a pilot study toward achieving the result reported in this study.Disclosure statementNo potential conflict of interest was reported by the author(s).Data availability statementThe authors want to declare that the data reported in this article can be deposited in a repository.","PeriodicalId":19742,"journal":{"name":"Particulate Science and Technology","volume":null,"pages":null},"PeriodicalIF":2.3000,"publicationDate":"2023-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Process optimization of nano-calcium carbonate produced from snail shell using supermasscollider\",\"authors\":\"Oluwatoyin Joseph Gbadeyan, Bruce Sithole, Sarp Adali, Glen Bright\",\"doi\":\"10.1080/02726351.2023.2274903\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"AbstractThis study uses the optimal (custom) design to focus on the supermasscolloider wet milling process for synthesizing calcium carbonate nanoparticles from the Achatina Fulica using the optimal (custom) design. The snail shell particle size of 150 μm from dry milling was wet milled to get smaller particle sizes. The response surface design method was used to investigate the effect of independent parameters such as consistency (amount of microparticle loading in calcium carbonate suspension) and the number of runs on the particle size of calcium carbonate produced using a supermasscolloider. Results show that the microparticle loading in calcium carbonate suspension and the number of runs significantly affected the synthesized particles. The increase in microparticle loading reduced the effectiveness of the supermasscolloider blade, resulting in the production of particle sizes ranging from 21- to 40 nm. A higher number of runs with a smaller loading of microparticles in calcium carbonate suspension offered a fine particle size of 21.30 nm. The experimental data quartic polynomial models gave a coefficient of determination (R2) of 0.92. The optimum milling runs of 750 and 1% consistency microparticle loading produced a calcium carbonate nanoparticle size of 21 nm. This technique has shown that calcium carbonate nanoparticles can be produced at low cost, at less period, with low agglomeration from Achatina Fulica shell using supermasscolloider.Keywords: Achatina fulica shellparticle sizenano-CaCo3supermasscolloidermilling processdesign expect AcknowledgmentsThe authors want to acknowledge the University of KwaZulu-Natal, where this research was conducted and that the abstract presented at PolyScience2022, having the same title as this manuscript, is entirely different from the result reported in this study. 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Process optimization of nano-calcium carbonate produced from snail shell using supermasscollider
AbstractThis study uses the optimal (custom) design to focus on the supermasscolloider wet milling process for synthesizing calcium carbonate nanoparticles from the Achatina Fulica using the optimal (custom) design. The snail shell particle size of 150 μm from dry milling was wet milled to get smaller particle sizes. The response surface design method was used to investigate the effect of independent parameters such as consistency (amount of microparticle loading in calcium carbonate suspension) and the number of runs on the particle size of calcium carbonate produced using a supermasscolloider. Results show that the microparticle loading in calcium carbonate suspension and the number of runs significantly affected the synthesized particles. The increase in microparticle loading reduced the effectiveness of the supermasscolloider blade, resulting in the production of particle sizes ranging from 21- to 40 nm. A higher number of runs with a smaller loading of microparticles in calcium carbonate suspension offered a fine particle size of 21.30 nm. The experimental data quartic polynomial models gave a coefficient of determination (R2) of 0.92. The optimum milling runs of 750 and 1% consistency microparticle loading produced a calcium carbonate nanoparticle size of 21 nm. This technique has shown that calcium carbonate nanoparticles can be produced at low cost, at less period, with low agglomeration from Achatina Fulica shell using supermasscolloider.Keywords: Achatina fulica shellparticle sizenano-CaCo3supermasscolloidermilling processdesign expect AcknowledgmentsThe authors want to acknowledge the University of KwaZulu-Natal, where this research was conducted and that the abstract presented at PolyScience2022, having the same title as this manuscript, is entirely different from the result reported in this study. The study presented was a pilot study toward achieving the result reported in this study.Disclosure statementNo potential conflict of interest was reported by the author(s).Data availability statementThe authors want to declare that the data reported in this article can be deposited in a repository.
期刊介绍:
Particulate Science and Technology, an interdisciplinary journal, publishes papers on both fundamental and applied science and technology related to particles and particle systems in size scales from nanometers to millimeters. The journal''s primary focus is to report emerging technologies and advances in different fields of engineering, energy, biomaterials, and pharmaceutical science involving particles, and to bring institutional researchers closer to professionals in industries.
Particulate Science and Technology invites articles reporting original contributions and review papers, in particular critical reviews, that are relevant and timely to the emerging and growing fields of particle and powder technology.