• Title/Summary/Keyword: KOH catalyst

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Characteristics of the Catalysts Using Activated Carbon Nanofibers with KOH as the Support of Anode Catalyst for Direct Methanol Fuel Cell

  • Jung, Min-Kyung;Kim, Sang-Kyung;Jung, Doo-Hwan;Peck, Dong-Hyun;Shin, Jung-Hee;Shul, Yong-Gun;Yoon, Seong-Ho
    • Carbon letters
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    • v.8 no.1
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    • pp.37-42
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    • 2007
  • Carbon nanofiber (CNF) grown catalytically was chemically activated with KOH to attain structural change of CNF. The structural changes of CNF through KOH activation were investigated by using BET and SEM. From the results of BET, it was found that KOH activation was effective to develop particular sizes of pores on the CNF surface, increasing the surface area of CNF. Activated CNF was applied as an anode catalyst support of fuel cell. The effects of different activation conditions including the activation temperature and the activation time on the specific surface area of the CNF activated with KOH were investigated to obtain appropriate structure as a catalyst support. The 60 wt% Pt-Ru catalyst prepared was observed by using TEM and XRD.

Biodiesel Production From Fat of Tra Catfish and Basa Catfish (Viet Nam) Using Alkaline Catalysts

  • Huong, Le Thi Thanh;Tan, Phan Minh;Hoa, Tran Thi Viet;Lee, Soo
    • Journal of the Korean Applied Science and Technology
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    • v.25 no.3
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    • pp.299-312
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    • 2008
  • The fat of Tra and Basa catfish (Mekong Delta, Viet Nam) was evaluated for the first time as the potential feedstock for biodiesel production, due to its abundance, availability and cheap cost. The unsaturated fatty acid contents of Tra and Basa fat were 57.97% and 64.17%, respectively. Biodiesel was prepared from Tra and Basa fat by methanolysis reaction using alkali catalysts like sodium hydroxide and potassium hydroxide. Effects of various process parameters on biodiesel production, such as molar ratio of methanol to fat, catalyst concentration, temperature and time were investigated. As those results, the transesterification can be performed under moderate conditions, and the biodiesel yields were shown more than 90%. KOH catalyst was the best catalyst for biodiesel production from both Basa and Tra fat. As the feedstock aspect, Basa fat was indicated more efficiency than that of Tra fat. The maximum yield could be achieved by the transesterification from Basa fat with 5:1 molar ratio of methanol to fat, 0.8% KOH catalyst, $50^{\circ}C$, and 50 min. For Tra fat, the optimal condition were at 6:1 molar ratio of methanol to fat, 0.8% KOH catalyst, $50^{\circ}C$, and 45 min. Nowadays, due to cheaper cost and abundance, Tra fat is a promised resource for cheap biodiesel production in Viet Nam.

Synthesis of Styrenated Phenol Alkoxylate from Styrenated Phenol with Ethylene Carbonate over KOH/La2O3 Catalyst (KOH/La2O3 촉매상에서 Styrenated Phenol과 Ethylene Carbonate의 반응으로부터 Styrenated Phenol Alkoxylate의 합성)

  • Lee, Seungmin;Son, Seokhwan;Jung, Sunghun;Kwak, Wonbong;Shin, Eun Ju;Ahn, Hogeun;Chung, Minchul
    • Applied Chemistry for Engineering
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    • v.29 no.1
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    • pp.62-66
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    • 2018
  • Styrenated phenol alkoxylates (SP-A) were prepared from styrenated phenol (SP) and ethylene oxide (EO) under a homogeneous base catalyst. However, to use EO that is difficult to handle, a high-pressure reaction device capable of controlling the reaction process should be used. Additionally, when a homogeneous base catalyst is used, a neutralization process is required to remove residual bases after the reaction, and it is also difficult to separate the catalyst and the product. Therefore, in this study, we report the results of SP-A prepared from the reaction of SP and EC using only heterogeneous base catalysts. The heterogeneous base catalyst was obtained by supporting KOH on $La_2O_3$ and calcintion. Using EC instead of EO, it was possible to produce SP-A under the atmospheric rather than high-pressure reaction condition. Average molecular weights of synthesized SP-A varied greatly depending on reaction conditions. The average molecular weight of SP-A prepared using the $KOH/La_2O_3$ catalyst could be controlled arbitrarily by controlling the reaction temperature and added catalyst and EC amounts.

Anionic Polymerization of 2-Pyrrolidone by $SO_2/KOH$ Catalyst ($SO_2/KOH$ 촉매에 의한 2-Pyrrolidone의 음이온 중합에 관한 연구)

  • Huh, Dong-Sub;Lee, Jung-Keun
    • Elastomers and Composites
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    • v.14 no.4
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    • pp.231-252
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    • 1979
  • Polymerization of 2-pyrrolidone was carried out through anionic mechanism using $SO_2/KOH$ as catalyst. The effects of KOH concentration, $SO_2/KOH$ mole ratio and temperature on polymerization were investigated. The conversion and viscosity of polymers were measured at various polymerization conditions. It was observed that as the concentration of KOH was increased, equilibrium conversion was also increased. It was, however, found that after the concentration of KOH was reached above 8 mole percent, the equilibrium conversion was decreased. The highest rate of polymerization and maximum conversion were obtained when $SO_2/KOH$ mole ratio was around 0.5. It was also found that the rate of polymerization and the equilibrium conversion were higher at $50^{\circ}C$. than at $30^{\circ}C$. but the viscosity of polymer solution at $50^{\circ}C$. was not so high as expected. The rate constant, $K_p$ of polymerization, was determined by least square method: the value of $K_p$ was observed as 16 liter/mole hour at $50^{\circ}C$. and 2.6 liter/mole hour at $30^{\circ}C$., respectively. The mechanism of polymerization was also discussed.

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Activating needle coke to develop anode catalyst for direct methanol fuel cell

  • Park, Young Hun;Im, Ui-Su;Lee, Byung-Rok;Peck, Dong-Hyun;Kim, Sang-Kyung;Rhee, Young Woo;Jung, Doo-Hwan
    • Carbon letters
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    • v.20
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    • pp.47-52
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    • 2016
  • Physical and electrochemical qualities were analyzed after KOH activation of a direct methanol fuel cell using needle coke as anode supporter. The results of research on support loaded with platinum-ruthenium suggest that an activated KOH needle coke container has the lowest onset potential and the highest degree of catalyst activity among all commercial catalysts. Through an analysis of the CO stripping voltammetry, we found that KOH activated catalysis showed a 21% higher electrochemical active surface area (ECSA), with a value of 31.37 m2 /g, than the ECSA of deactivated catalyst (25.82 m2 /g). The latter figure was 15% higher than the value of one specific commercial catalyst (TEC86E86).

Fabrication of a solid catalyst using coal fly ash and its utilization for producing biodiesel

  • Go, Young Wook;Yeom, Sung Ho
    • Environmental Engineering Research
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    • v.24 no.2
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    • pp.324-330
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    • 2019
  • To recycle raw fly ash (RFA), a waste from thermal power plants, it was used to prepare solid catalysts which have many advantages compared with homogenous catalysts. When biodiesel was produced from soybean oil using RFA, only 1.2% of biodiesel conversion was obtained. A metal hydroxide, NaOH, KOH or $Ca(OH)_2$, was mixed with the acid-treated fly ash (ATFA), and the mixture was calcined at $700^{\circ}C$ for 3 h to prepare the solid catalyst. The solid catalyst prepared by mixing ATFA with NaOH, designated as SC-Na, showed a better performance than those prepared by mixing ATFA with KOH or $Ca(OH)_2$, respectively. The optimal mass ratio of ATFA with NaOH was 1:3, at which the proportion of $Na_2O$ increased to 60.2% in SC-Na, and 97.8% of biodiesel conversion was achieved under optimal reaction conditions (2 w% SC-Na relative to oil and 5 mL-methanol/g-oil at $50^{\circ}C$ for 4 h). Finally, a batch operation was repeatedly carried out to test the feasibility of reusing the solid catalyst, and more than 96% biodiesel conversion was stably achieved for the third round of operations. This study shows that RFA was successfully recycled to solid catalysts through a simple preparation method, and the solid catalyst was reused for the production of biodiesel with high conversion.

Biodiesel Porduction with KOH/$Al_2O_3$ catalyst as various calcination temperature (KOH/$Al_2O_3$ 촉매의 소성온도에 따른 바이오디젤 합성 특성)

  • Chang, Duk-Rye;Oh, Mi-Young
    • 한국신재생에너지학회:학술대회논문집
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    • 2008.10a
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    • pp.85-86
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    • 2008
  • 바이오디젤은 식물성 기름이나 동물성 지방과 같은 재생 가능한 생물학적 원료를 사용하여 생산되는 대체연료이다. 이는 생분해가 가능하고 무독성이며 낮은 배기 특성으로 인하여 친환경적 자원으로 인식되고 있다. 본 연구에서는 20 wt% KOH/$Al_2O_3$ 촉매를 $500^{\circ}C{\sim}1200^{\circ}C$ 소성온도에 따라 제조하여 XRD, SEM 및 BET를 이용하여 촉매의 특성을 조사 하였고, 제조된 촉매의 사용에 의한 바이오디젤 제조에 미치는 영향에 대해 조사하였다.

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Conversion of Jatropha Oil into Biodiesel in Continuous Process Using Alkali and Mixed Catalysts (연속공정에서 알칼리 및 혼합촉매를 사용한 자트로파유의 바이오디젤화)

  • Hyun, Young-Jin
    • Journal of the Korean Applied Science and Technology
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    • v.26 no.4
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    • pp.394-399
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    • 2009
  • The esterification of palmitic acid in Jatropha Oil using 8wt% p-TSA catalyst was done at the 1:8 molar ratio of oil to methanol and $65^{\circ}C$. The conversion of palmitic acid appeared to be 95.3% in 60min. After that, the continuous transesterification of the oil using 0.5wt% KOH, 0.8wt% TMAH mixed catalyst[40vol% KOH(0.5wt%) + 60vol% TMAH(0.8wt%)] and 1.1wt% TMAH was conducted with the flow rates and the molar ratios at $65^{\circ}C$. The overall conversion of Jatropha Oil increased with the decrease of flow rate and showed 95.6% with 9ml/min of flow rate at the 1:8 molar ratio of oil to methanol and $65^{\circ}C$. But it showed 87% with 15ml/min of flow rate at the same conditions. The recovery of methanol(%) appeared to be 86% at the 1:8 molar ratio of oil to methanol, mixed catalyst and $65^{\circ}C$.

CO2 conversion technology for CO gas synthesis using coal (석탄을 사용한 CO가스 제조를 위한 CO2 전환기술)

  • Lee, Ho-Yong;Park, Ji-Yong;Lee, Jong-Dae
    • Journal of the Korean Applied Science and Technology
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    • v.32 no.4
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    • pp.712-717
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    • 2015
  • In this study, the experiment of CO production was performed using carbon dioxide and coal. The synthesis characteristics of CO gas was investigated using the chemical activation method of KOH. The preparation process has been optimized through the analysis of experimental variables such as activating chemical agents to coal ratio, the flow rate of gas and reaction temperature during $CO_2$ conversion reaction. Without the catalyst of KOH, the 66.7% of $CO_2$ conversion was obtained at the conditions of $T=950^{\circ}C$ and $CO_2$ flow rate of 300 cc/min. On the other hand, the 98.1% of $CO_2$ conversion was obtained using catalyst of KOH at same conditions. It was found that the feed ratio(Coal : KOH = 4 : 1) had better $CO_2$ conversion and CO selectivity than other feed ratios.