• 제목/요약/키워드: Hydrogen Impurity

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Effect of CO in Anode Fuel on the Performance of Polymer Electrolyte Membrane Fuel Cell (수소연료 중 일산화탄소의 고분자전해질 연료전지에 대한 영향)

  • Kwon, Jun-Taek;Kim, Jun-Bum
    • Journal of Hydrogen and New Energy
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    • v.19 no.4
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    • pp.291-298
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    • 2008
  • Carbon monoxide(CO) is one of the contamination source in reformed hydrogen fuel with an influence on performance of polymer electrolyte membrane fuel cell(PEMFC). The studies of CO injection presented here give information about poisoning and recovery processes. The aim of this research is to investigate cell performance decline due to carbon monoxide impurity in hydrogen. Performance of PEM fuel cell was investigated using current vs. potential experiment, long time(10 hours) test, cyclic feeding test and electrochemical impedance spectra. The concentrations of carbon monoxide were changed up to 10 ppm. Performance degradation due to carbon monoxide contamination in anode fuel was observed at high concentration of carbon monoxide. The CO gas showed influence on the charge transfer reaction. The performance recovery was confirmed in long time test when pure hydrogen was provided for 1 hour after carbon monoxide had been supplied. The result of this study could be used as a basis of various reformation process design and fuel quality determination.

Effect of Carbon dioxide in Fuel on the Performance of PEM Fuel Cell (연료중의 이산화탄소 불순물에 의한 연료전지 성능변화 연구)

  • Seo, Jung-Geun;Kwon, Jung-Taek;Kim, Jun-Bom
    • 한국신재생에너지학회:학술대회논문집
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    • 2007.11a
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    • pp.184-187
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    • 2007
  • Hydrogen could be produced from any substance containing hydrogen atoms, such as water, hydrocarbon (HC) fuels, acids or bases. Hydrocarbon fuels couold be converted to hydrogen-rich gas through reforming process for hydrogen production. Even though fuel cell have high efficiency with pure hydrogen from gas tank, it is more beneficial to generate hydrogen from city gas (mainly methane) in residential application such as domestic or office environments. Thus hydrogen is generated by reforming process using hydrocarbon. Unfortunately, the reforming process for hydrogen production is accompanied with unavoidable impurities. Impurities such as CO, $CO_2$, $H_2S$, $NH_3$, and $CH_4$ in hydrogen could cause negative effects on fuel cell performance. Those effects are kinetic losses due to poisoning of electrode catalysts, ohmic losses due to proton conductivity reduction including membrane and catalyst ionomer layers, and mass transport losses due to degrading catalyst layer structure and hydrophobic property. Hydrogen produced from reformer eventually contains around 73% of $H_2$, 20% or less of $CO_2$, 5.8% of less of $N_2$, or 2% less of $CH_4$, and 10ppm or less of CO. Most impurities are removed using pressure swing adsorption (PSA) process to get high purity hydrogen. However, high purity hydrogen production requires high operation cost of reforming process. The effect of carbon dioxide on fuel cell performance was investigated in this experiment. The performance of PEM fuel cell was investigated using current vs. potential experiment, long run (10 hr) test, and electrochemical impedance measurement when the concentrations of carbon dioxide were 10%, 20% and 30%. Also, the concentration of impurity supplied to the fuel cell was verified by gas chromatography (GC).

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The performance of PEMFC during exposure to simultaneous sulfur impurity poisoning on cathode and anode (공기극과 연료극의 복합 황불순물에 의한 고분자 전해질막 연료전지의 성능에 미치는 영향)

  • Lee, Soo;Jin, Seok-Hwan
    • Journal of the Korean Applied Science and Technology
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    • v.29 no.4
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    • pp.594-598
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    • 2012
  • Polymer electrolyte membrane fuel cell(PEMFC) performance degrades seriously when sulfur dioxide and hydrogen sulfide are contaminated in the fuel gas at anode and air source at cathode, respectively. This paper reveals the effect of the combined sulfur impurity poisoning on both PEMFC cathode and anode parts through measuring electrical performance on single FC operated under 1 ppm to 10 ppm impurity gases. The severity of $SO_2$ and $H_2S$ poisoning depended on concentrations of impurity gases under optimum operating conditions($65^{\circ}C$ of cell temperature and 100 % relative humidity). Sulfur adsorption occured on the surface of Pt catalyst layer on MEA. In addition, MEA poisoning by impurity gases were cumulative. After four consecutive poisonings with 1, 3, 5 to 10 ppm, the fuel cell performance of PEMFC was decrease upto 0.54 V(76 %) from 0.71 V.

The Effect of Methane in Hydrogen on the Performance of Proton Exchange Membrane Fuel Cell (수소연료 중의 메탄에 의한 고분자전해질 연료전지 성능변화 연구)

  • Seo, Jung-Geun;Kwon, Jun-Taek;Kim, Jun-Bum;Chung, Jong-Tae;Kim, Woo-Sik
    • Journal of Hydrogen and New Energy
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    • v.18 no.4
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    • pp.432-438
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    • 2007
  • The reforming process for hydrogen production generates some impurities. Impurities in hydrogen such as $CO_2$, CO, $H_2S$, $NH_3$ affect fuel cell performance. It is well known that CO generated by the reforming process may negatively affect performance of cell, cause damage on catalysts resulting performance degradation. Hydrogen produced by reforming process includes about 2% methane. The presence of methane up to 10% is reported negligible degradation in cell performance. However, methane more than 10% in hydrogen stream had not been researched. The concentration of impurity supplied to the fuel cell was verified by gas chromatography(GC). In this study, the influence of $CH_4$ on performance of PEM fuel cell was investigated by means of current vs. potential experiment, long run(10 hr) test and electrochemical impedance measurement when the concentrations of impurities were 10%, 20% and 30%.

A Study on Hydrogen Impurity Effect in Anode of Proton Exchange Membrane Fuel Cell on Various Concentration of CO and H2S (고분자전해질 연료전지 연료극의 일산화탄소 및 황화수소 농도에 따른 불순물영향에 관한 연구)

  • LEE, EUN-KYUNG;BAEK, JAE-HOON;LEE, JUNG-WOON;LEE, SEUNG-KUK;LEE, YEON-JAE
    • Journal of Hydrogen and New Energy
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    • v.27 no.6
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    • pp.670-676
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    • 2016
  • Hydrogen town in Republic of Korea was established in 2013. Hydrogen as a byproduct produced by various processes of factories is used in hydrogen town facilities. As cell performance is affected by contaminations in fuel gas, various standards about impurities of fuel have been determined by many countries. This study shows performance degradation of single cell with impurities concentrations. Traces of carbon monoxide (CO) and hydrogen sulfide ($H_2S$)can cause considerable cell performance losses. For comparing the performances by poisoning of CO, acceleration test, I-V curve, constant current are performed. Both the CO and $H_2S$ poisoning rate are a function of their concentration. With the higher concentrations the higher poisoning rates are observed. And, it was confirmed that, oxidation behavior and side reaction generation are not affected. Under the lower $H_2S$ concentration condition, the poisoning rate is much higher than that of CO because of its different adsorption intensity. It can be possible that the result of this study can be used for enacting regulation as a baseline data.

Effects of $\beta$-Mercaptoethanol and Hydrogen Peroxide on Enzymatic Conversion of Human Proinsulin to Insulin

  • Son, Young-Jin;Kim, Chang-Kyu;Choi, Byoung-Taek;Park, Yong-Cheol;Seo, Jin-Ho
    • Journal of Microbiology and Biotechnology
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    • v.18 no.5
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    • pp.983-989
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    • 2008
  • Human insulin is a hormone well-known to regulate the blood glucose level. Recombinant preproinsulin, a precursor of authentic insulin, is typically produced in E. coli as an inactive inclusion body, the solubilization of which needs the addition of reducing agents such as $\beta$-mercaptoethanol. To make authentic insulin, recombinant preproinsulin is modified enzymatically by trypsin and carboxypeptidase B. The effects of $\beta$-mercaptoethanol on the formation of human insulin derivatives were investigated in the enzymatic modification by using commercially available human proinsulin as a substrate. Addition of 1 mM $\beta$-mercaptoethanol induced the formation of various insulin derivatives. Among them, the second major one, impurity 3, was found to be identical to the insulin B chain fragment from $Phe_1$ to $Glu_{21}$. Minimization of the formation of insulin derivatives and concomitant improvement of the production yield of human insulin were achieved by the addition of hydrogen peroxide. Hydrogen peroxide bound with $\beta$-mercaptoethanol and thereby reduced the negative effects of $\beta$-mercaptoethanol considerably. Elimination of the impurity 3 and other derivatives by the addition of over 10 mM hydrogen peroxide in the presence of $\beta$-mercaptoethanolled to a 1.3-fold increase in the recovery efficiency of insulin, compared with those for the case without hydrogen peroxide. The positive effects of hydrogen peroxide were also confirmed with recombinant human preproinsulin expressed in recombinant E. coli as an inclusion body.

An impurity analysis study in ultra high purity Hydrogen stream: The utilization of Atmosperic Pressure Ionization Mass Spectrometer (고순도 수소가스내에 존재하는 불순물의 분석 연구: 대기압 이온화 질량분석기의 이용)

  • Lee, H.S.;Lee, T.H.
    • Journal of Hydrogen and New Energy
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    • v.16 no.3
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    • pp.290-295
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    • 2005
  • For the application of fuel cell, the content and concentration of impurities in hydrogen stream must be classified. The purpose of this study is to provide analysis tool for the determination of impurities in hydrogen with ultra high purity. To produce UHT hydrogen, we purified hydrogen gas by both getter-based catridge and liquid-nitrogen soaked catridge. We compare two methods and propose new method to know about what is in hydrogen stream.

Phase Separation Characteristics via Bunsen Reaction in Sulfur-Iodine Thermochemical Hydrogen Production Process (SI 열화학 수소 제조 공정에서 분젠 반응을 통한 상 분리 특성)

  • Lee, Kwang-Jin;Kim, Young-Ho;Park, Chu-Sik;Bae, Ki-Kwang
    • Journal of Hydrogen and New Energy
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    • v.19 no.5
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    • pp.386-393
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    • 2008
  • The Sulfur-iodine(SI) thermochemical cycle is one of the most promising methods for massive hydrogen production. For the purpose of continuous operation of SI cycle, phase separation characteristics into two liquid phases ($H_2SO_4$-rich phase and $HI_x$-rich phase) were directly investigated via Bunsen reaction. The experiments for Bunsen reaction were carried out in the temperature range, from 298 to 333 K, and in the $I_2/H_2O$ molar ratio of $0.109{\sim}0.297$ under a continuous flow of $SO_2$ gas. As the results, solubility of $SO_2$, decreased with increasing the temperature, had considerable influence on the global composition in the Bunsen reaction system. The amounts of impurity in each phase(HI and $I_2$ in $H_2SO_4$-rich phase and $H_2SO_4$ in $HI_x$-rich phase) were decreased with increasing $H_2SO_4$ molar ratio and temperature. To control the amounts of impurity in $HI_x$-rich phase, temperature is a factor more important than $I_2/H2_O$ molar ratio. On the other hand, the affinity between $HI_x$ and $H_2O$ was increased with increasing $I_2/H2_O$molar ratio.

Hydrogen Impurities Analysis From Proton Exchange Membrane Hydrogen Production (양자교환막을 이용하여 생산된 수소의 불순물 분석)

  • Lee, Taeckhong;Kim, Taewan;Park, Taesung;Choi, Woonsun;Kim, Hongyoul;Lee, Hongki
    • Journal of Hydrogen and New Energy
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    • v.24 no.4
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    • pp.288-294
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    • 2013
  • This gas analysis data come from the hydrogen which is produced by proton exchange membrane. Main impurities of hydrogen are methane, oxygen, nitrogen, carbon monoxide, and carbon dioxide. The concentration of impurities is ranged between 0.0191 to $315{\mu}mol/mol$ for each impurity. Methane contamination is believed from the electrode reaction between carbon doped electrode and produced hydrogen. Nitrogen contamination should take place the sampling process error, not from PEM hydrogen Production system.