• Title/Summary/Keyword: thermochemical water-splitting IS process

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Evaluation on the Electro-electrodialysis for hydrogen production by thermochemical water-splitting IS process (열화학적 수소제조 IS 프로세스의 효율향상을 위한 전해-전기투석의 실험적 평가)

  • Hong, Seong-Dae;Kim, Jeong-Geun;Lee, Sang-Ho;Choi, Sang-Il;Bae, Ki-Kwang;Hwang, Gab-Jin
    • 한국신재생에너지학회:학술대회논문집
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    • 2006.06a
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    • pp.13-16
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    • 2006
  • Electro-electrodialysis (EED) experiments were carried out for the HI concentration from HIx $(HI-H_2O-I_2)$ solution to improve the Hl decomposition reaction in the thermochemical water-splitting is (iodine-Sulfur) process. EED cell is composed of the collector electrode and electrolyte. Nafion 117 which was cation exchange membrane used as an electrolyte, and the activated carbon cloth used as an electrode. The HI concentration experiment was carried out using the HIx solution and molar ratio of the $I_2$ were varied from 1 to 3 mole. The cell voltages were decreased as temperature increase. And, membrane properties such as transport number of proton and electro-osmosis coefficient were decreased as temperature increase

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Application of the Membrane Technology in Thermochemical Hydrogen Production Process using High Temperature Nuclear Heat (원자력의 고온 핵열을 이용한 열화학적 수소제조 프로세스에의 분리막 기술의 응용)

  • 황갑진;박주식;이상호;최호상
    • Proceedings of the Membrane Society of Korea Conference
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    • 2003.11a
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    • pp.25-33
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    • 2003
  • It summarized about the application of the membrane technology in thermochemical water-splitting iodine-sulfur process that was hydrogen production using the nuclear heat from the High Temperature Gas-Cooled Reactor (HTGR). Thermochemical water-splitting hydrogen production method using the high temperater nuclear thermal energy could be realized and remained to be solved the investigation subject. And, it is possible for mass-production of hydrogen such as one of the clean energy in future.

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Application of Membrane Technology in Thermochemical Hydrogen Production IS (iodine-sulfur) Process Using the Nuclear Heat (원자력 고온 핵 열을 이용한 열화학적 수소제조 IS(요오드-황) 프로세스에서의 분리막 기술의 이용)

  • Hwang Gab-Jin;Park Chu-Sik;Lee Sang-Ho;Kim Tae-Hwan;Choi Ho-Sang
    • Membrane Journal
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    • v.14 no.3
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    • pp.185-191
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    • 2004
  • It summarized about the properties of thermochemical water-splitting iodine-sulfur process that was hydrogen production using the waste heat from the High Temperature Gas-Cooled Reactor (HTGR) recycling the heat of nuclear power. It was mainly explained about the application of membrane separation technique in IS process. Thermochemical water-splitting hydrogen production method using the high temperature nuclear thermal energy could be realized and remained to be solved the investigation subject. And, it is possible for mass-production of hydrogen such as one of the clean energy in future.

2-Step Thermochemical Water Splitting on a Active Material Washcoated Monolith Using a Solar Simulator as Heat Source (인공태양을 이용한 모노리스 적용 반응기에서 2단계 열화학적 물분해 연구)

  • Kang, Kyoung-Soo;Kim, Chang-Hee;Park, Chu-Sik
    • Journal of Hydrogen and New Energy
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    • v.18 no.2
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    • pp.109-115
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    • 2007
  • Solar energy conversion to hydrogen was carried out via a two-step thermochemical water splitting using metal oxide redox pair. To simulate the solar radiation, a 7 kW short arc Xe-lamp was used. Partially reduced iron oxide and cerium oxide have the water splitting ability, respectively. So, $Fe_3O_4$ supported on $CeO_2$ was selected as the active material. $Fe_3O_4/CeO_2$(20 wt/80 wt%) was prepared by impregnation method, then the active material was washcoated on the ceramic honeycomb monolith made of mullite and cordierite. Oxygen was released at the reduction step($1673{\sim}1823\;K$) and hydrogen was produced from water at lower temperature($873{\sim}1273\;K$). The result demonstrate the possibility of the 2-step thermochemical water splitting hydrogen production by the active material washcoated monolith. And hydrogen and oxygen was produced separately without any separation process in a monolith installed reactor. But the SEM and EDX analysis results revealed that the support used in this experiment is not suitable due to the thermal instability and coating material migration.

The Preparation Characteristics of Hydrogen Permselective Membrane in IS Process of Nuclear Hydrogen Production (원자력 수소제조 IS 공정의 수소분리막 제조 특성)

  • Son, Hyo-Seok;Choe, Ho-Sang;Kim, Jeong-Min;Hwang, Gap-Jin;Park, Ju-Sik;Bae, Gi-Gwang
    • Proceedings of the Membrane Society of Korea Conference
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    • 2005.11a
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    • pp.119-123
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    • 2005
  • The thermochemical splitting of water has been proposed as a clean method for hydrogen production. The IS process is one of the thermochemical water splitting processes using iodine and sulfur as reaction agents. HI decomposition procedure to obtain hydrogen is one of the key operations in the process, because equilibrium conversion of HI is low (22% at $450^{\circ}C$). The silica membranes prepared by CVD. method were applied to the decomposition reaction of HI vapor. The permeation characteristics of hydrogen and nitrogen belong to the Knudsen flow pattern.

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Improvement of the Thermochemical water-splitting IS Process Using the Membrane Technology (분리막 기술을 이용한 열화학적 수소제조 IS[요오드-황] 프로세스의 개선)

  • Hwang, Gab-Jin;Kim, Jong-Won;Sim, Kyu-Sung
    • Journal of Hydrogen and New Energy
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    • v.13 no.3
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    • pp.249-258
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    • 2002
  • Thermochemical water-splitting IS(Iodine-Sulfur) process has been investigating for large-scale hydrogen production. For the construction of an efficient process scheme, two kinds of membrane technologies are under investigating to improve the hydrogen producing HI decomposition step. One is a concentration of HI in quasi-azeotropic HIx ($HI-H_2O-I_2$) solution by elecro-electrodialysis. It was confirmed that HI concentrated from the $HI-H_2O-I_2$ solution with a molar ratio of 1:5:1 at $80^{\circ}C$. The other is a membrane reactor to enhance the one-pass conversion of thermal decomposition reaction of gaseous hydrogen iodide (HI). It was found from the simulation study that the conversion of over 0.9 would be attainable using the membrane reactor using the gas permeation properties of the prepared silica hydrogen permselective membrane by chemical vapor deposition (CVD). Design criterion of the membrane reactor was also discussed.

Bench-scale Test of Sulfuric Acid Decomposition Process in SI Thermochemical Cycle at Ambient Pressure (SI 열화학싸이클 황산분해공정의 Bench-scale 상압 실험)

  • Jeon, Dong-Keun;Lee, Ki-Yong;Kim, Hong-Gon;Kim, Chang-Soo
    • Journal of Hydrogen and New Energy
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    • v.22 no.2
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    • pp.139-151
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    • 2011
  • The sulfur-iodine (SI) thermochemical water splitting cycle is one of promising hydrogen production methods from water using high-temperature heat generated from a high temperature gas-cooled nuclear reactor (HTGR). The SI cycle consists of three main units, such as Bunsen reaction, HI decomposition, and $H_2SO_4$ decomposition. The feasibility of continuous operation of a series of subunits for $H_2SO_4$ decomposition was investigated with a bench-scale facility working at ambient pressure. It showed stable and reproducible $H_2SO_4$ decomposition by steadily producing $SO_2$ and $O_2$ corresponding to a capacity of 1 mol/h $H_2$ for 24 hrs.

Gas Permeation Characteristics of the Prepared SiC Membrane through Polyimide Carbonization Treatmemt (폴리이미드의 탄화 처리에 의한 SiC 분리막의 가스투과 특성)

  • Choi, Ho-Sang;Hwang, Gab-Jin;Kang, An-Soo
    • Korean Chemical Engineering Research
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    • v.43 no.1
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    • pp.66-70
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    • 2005
  • For the application in HI decomposition reaction of thermochemical water-splitting IS process, the carbonized membranes using the polymer material (polyimide) were prepared, and SiC membrane was also prepared by SiO treatment on those carbonized membranes. The weight change by the carbonation of polyimide was about 50%, and the weight decreased with an increase of carbonation temperature. The gas permeance ($H_2$ or $N_2$) of carbonized membrane decreased with an increase of carbonation temperature led to the pore closing. The gas permeance ($H_2$ or $N_2$) of SiC membrane increased with an increase of SiO treatment concentration, and the gas permeation mechanism was changed from the activiation energy flow to Knudsen flow.

Themochemical Cycles for Hydrogen Production from Water (열화학적 수소 제조 기술)

  • Kim J.W.;Park C.S.;Hwang G.J.;Bae K.K.
    • Journal of Energy Engineering
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    • v.15 no.2 s.46
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    • pp.107-117
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    • 2006
  • The status of water splitting thermochemical cycle for hydrogen production was reviewed in this article. Mass production of hydrogen could be possible using the thermochemical process which is similar to the concept of conventional chemical reaction system if the high temperature heat source is available. The mediators (chemicals and reagents) should be used to split chemically stable water, and should be recycled in a closed cycle in order to be environmentally acceptable. Though there is no process to reach commercial stage, IS cycle, two-step cycles based on metallic oxide such as ZnO/Zn, $Fe_3O_4/FeO$ and the associated cycles are attracted due to their possibilities of application. Development of materials for high temperature and/or corrosive conditions during thermochemical process is still important topic in some thermochemical processes.

Calculation of Mass-Heat Balance on the Iodine Crystallizer for SI Thermochemical Hydrogen Production Process (SI 열화학 수소 생산 공정 요오드 결정화기 열-물질 수지 계산)

  • Lee, Pyoung Jong;Park, Byung Heung
    • Journal of Institute of Convergence Technology
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    • v.5 no.1
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    • pp.1-5
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    • 2015
  • SI thermochemical hydrogen production process achieves water splitting into hydrogen and oxygen through three chemical reactions. The process is comprised of three sections and one of them is HI decomposition into $H_2$ and $I_2$ called as Section III. The production of $H_2$ included processes involving EED for concentrating a product stream from Section I. Additionally an $I_2$ crystallization would be considered to reduce burden on EED by removing certain amount of $I_2$ out of a process stream prior to EED. In this study, the current thermodynamic model of SI process was briefly described and the calculation results of the applied Electrolytes NRTL model for phase equilibrium calculations was illustrated for ternary systems of Section III. We calculated temperature and heat duty of an $I_2$ crystallizer and heat duty of heaters using UVa model and heat balance equation of simulation tool. The results were expected to be used as operation information in optimizing HI decomposition process and setting up material balance throughout SI process.