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会议名称:

World hydrogen energy conference

召开年:

2016

召开地:

Zaragoza

会议文集:

21st world hydrogen energy conference 2016: 21st world hydrogen energy conference 2016 (WHEC 2016), 13-16 June 2016, Zaragoza, Spain

主办单位:

Spanish Hydrogen Association

出版时间:

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  • 题名 作者 来源 发表时间 操作
  • Using cryogenic separation of anode off gases for high temperature fuel cell applications

    作者:J. Mile ski;R. Bernat; 会议名称:World hydrogen energy conference 2016年

    Environmental concerns regarding greenhouse gas emissions and depletion of fossil fuel deposits have driven significant research and development into alternative, clean energy sources [8, 17]. Fuel cells present very promising technologies, mainly due to the fact that their electricity generation is not based on a heat engine, which requires a working agent. Additional benefits could be obtained through combining fuel cells with gas turbines, which could theoretically achieve very high efficiency—over 70% though not proven to date. Thus, improving the performance of a hybrid solid oxide fuel cell gas turbine system is still under investigation [1]. This can done by estimating the geometric parameters of the turbomachinery components, which shows a clear efficiency advantage for the whole operating range. The aim of this paper is to investigate the possibility of using cryogenic separation [19] to improve the efficiency of high temperature fuel cells (Solid Oxide Fuel Cell— SOFC [7, 10, 13, 18, 24], Molten Carbonate Fuel Cell— MCFC [12, 16, 23]) by condensing H_2O and CO_2 from anode off gases and returning hydrogen to the anode inlet: There are two factors which should be taken "into consideration: (1) Energy penalty of cryogenic- process, (2) Fuel chemical energy saved. Moreover, pure CO_2 can subject to co-electrolysis with H2O in/ a Solid Oxide Electrolyzer Cell [22]. The proposed solution cannot be utilized in other fuel cells (e.g. PEMFC [9, 15]) as they utilize hydrogen completely. Thus, based on theoretical investigation the most preferred system configurations are presented. The issue of using a cryogenic chiller to separate/ gases was the subject of various analyses. The most popular,' is using cryogenic separation as Jan alternative to other carbon capture technologies [2]. In [14], a contextualized overview of CO_2 capture technology/is presented, with critical evaluation of the-state 'of, tlie art and technological development through patent applications and scientific articles; The mapping of capture technologies focused on absorption, adsorption, membranes, cryogenic,.enzyrriatic and hybrid splutions. In [-11], energy-efficient distributed carbon capture in hydrogen production.was demonstrated with an advanced membrane reformer system. An apparatus for CO_2 capture was combined with the membrane refofmeT system and -over 90$ of the CO_2 in the reactor...p,ff gas was captured by cryogenic separation. The total energy efficiency of hydrpgen'production with CO_2 capture was 78.6% (HHV). The performance of an advanced cycle with;low CO_2 emissions" where a Molten Carbonate.Fuel Cell is used to separate the CO2 from the gas turbine exhaust of a natural gas fired'combined cycle-power plant is shown in [6]. The CO2 is concentrated on the anode side of the MCFC allowing one to easily -treat this spent fuel stream in a cryogenic process to split combustible species (routed back to the gas-turbine combustor) from the CO_2 addressed to storage. The paper concludes that the configuration'-with CO2 cryogenic separationjbehaves better in terms of efficiency and specific energy consumption for CO_2 avoided than; CO_2 separation via oxyfuel combustion,even with a slightly lower carbon capture ratio. An investigation is presented in [3] of the potential of a hybrid process combining membrane and. cryogenic separation to achieve efficient post-combustion carbon capture.;1 The hybrid process combines a first step CO_2 pre-concentration with a membrane Unit and a second step CO2 cryogenic condensation. A concept of cryogenic CO_2 capture technology based on a free piston Stirling cooler is proposed in [20, 21]. Moisture and CO_2 in the flue gas can condense and desublimate in the prefreezing and mainfreezing towels, respectively. The whole process can be implemented at atmospheric pressure. The optimal conditions for the system are as follows: idle operating time is 240 min, flow rate is 5 L/min, vacuum degree of the inter layer is 2.2×10~3 Pa, and temperatures in the range --30...--120 °C. The energy consumption of the system is around 0.5 MJ_(electrical)/kg CO_2 with above 90% CO_2 recovery. Energy penalty figures for low-temperature capture from flue gas and synthesis gas, shown in Fig. 1, are valid for the CO_2 capture unit process boundaries only. They do not account for additional energy penalties from other ancillary processes such as cryogenic air separation, gasification, reforming, wateregas shift or sulfur removal. In [5], the anode exhaust stream of the MCFC, where most of the CO_2is concentrated, is sent to a CO_2 purification section which can be based on a cryogenic CO_2 separation section, followed by cooling, condensation of water and separation of CO_2 (see Fig. 2). A high purity CO_2 stream is obtained and pumped to liquid form for storage.

    关键字:

  • Using cryogenic separation of anode off gases for high temperature fuel cell applications

    J. Mile ski;R. Bernat;

    World hydrogen energy conference

    2016年

  • Modeling of partial oxidation of natural gas in a porous catalytic bed

    作者:A. Al-Musa;S. Shabunya;M. Al-Johani;V. Martynenko;M. Al-Saleh;A. Al-Zahrani;V.Kalinin; 会议名称:World hydrogen energy conference 2016年

    Active use of synthesis gas in the industry has stimulated researches aimed at improving the methods for production thereof. Most of the synthesis gas is produced by steam reforming of natural gas, which requires external heating to compensate for process endothermicity. The efficiency of this technology is growing with the performance; therefore, its use is more reasonable for large-scale production [1]. An alternative method for producing synthesis gas is the catalytic partial oxidation of natural gas, which is moderately exothermic, and may be organized as self-sustaining process. The effectiveness of such techniques is almost independent of the production scale.

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  • Modeling of partial oxidation of natural gas in a porous catalytic bed

    A. Al-Musa;S. Shabunya;M. Al-Johani;V. Martynenko;M. Al-Saleh;A. Al-Zahrani;V.Kalinin;

    World hydrogen energy conference

    2016年

  • Highly efficient solar hydrogen generation

    作者:Arne Fallisch;Paul Forster;Mario Zedda;Jens Ohlmann; 会议名称:World hydrogen energy conference 2016年

    Hydrogen production by proton exchange membrane (PEM) water electrolysis is considered as a highly efficient and sustainable technology with the aim to establish hydrogen as an energy carrier. To achieve a sustainable hydrogen production, the electrolysis system must be coupled to renewable energies like wind or solar. In a conventional approach an electrolyzer is coupled by one or two converters to several solar modules, which are in most cases not customized. Using the concept of a "Hydrogen Concentrator" (HyCon® [1]) enables the direct connection of solar cells to electrolysis cells . In the HyCon® project, one major goal is to achieve an efficiency for solar to hydrogen conversion of more than 20%.

    关键字:

  • Highly efficient solar hydrogen generation

    Arne Fallisch;Paul Forster;Mario Zedda;Jens Ohlmann;

    World hydrogen energy conference

    2016年

  • Hydrogen Generation from (Bio)Alcohols, Sugars and Biomass

    作者:Henrik Junge;Matthias Beller; 会议名称:World hydrogen energy conference 2016年

    Enabling a sustainable energy system "green" hydrogen generation from the combination of renewable energy and resources, such as water and biomass, is highly desirable. Although in recent years the use of bio-alcohols and carbohydrates for hydrogen production has attracted much attention, the current state-of-the-art of catalytic reforming still lacks of high temperatures (>200 °C), pressures (25-50 bars) and low selectivity. In order to overcome these drawbacks a possible key to success is the application of molecular-defined metal HPNP pincer type complexes as homogeneous catalysts. As we recently demonstrated, these exhibit nigh activities and productivities in hydrogen generation from various bio related alcohols. As a first example it was possible to perform a low temperature aqueous methanol reforming process to hydrogen and carbon dioxide employing ruthenium pincer complexes. Notably, the hydrogen generation proceeded at 70-95 °C and ambient pressure with excellent catalyst turnover frequencies (5000 rr1) and turnover numbers (>350,000) [1] (Figure 1).

    关键字:

  • Hydrogen Generation from (Bio)Alcohols, Sugars and Biomass

    Henrik Junge;Matthias Beller;

    World hydrogen energy conference

    2016年

  • Power-to-SNG technology for energy storage at large scales

    作者:F. Gutierrez-Martin;L.M. Rodriguez-Anton; 会议名称:World hydrogen energy conference 2016年

    This work analyzes the main technical, economic and environmental aspects of "power-to-gas' (PtG) technologies, dealing with the basic components that are shown in Fig. 1. The primary energy input is surplus power from electric grid and the process consists out of two steps: water electrolysis and methanation of hydrogen; both steps for their own are not new, it is their combinations and integration into the energy system the innovative element; the synthetic methane (SNG) has several advantages over H_2, while the O_2 by-product is coupled to oxi-fuel combustion thereby facilitating flue gas capture as it is composed of CO_2 and H_2O; this provides a massive system to store the electricity by means of chemical energy carriers where the processes are theoretically circular and carbon neutral.

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  • Power-to-SNG technology for energy storage at large scales

    F. Gutierrez-Martin;L.M. Rodriguez-Anton;

    World hydrogen energy conference

    2016年

  • Hydrogen production by coupling pressurized high temperature electrolyser with solar tower technology

    作者:N. Monnerie;A. Houaijia;M. Roeb;C. Sattler; 会议名称:World hydrogen energy conference 2016年

    Solar hydrogen production by coupling pressurized high temperature electrolyser with concentrated solar tower technology is studied. As the high temperature electrolyser needs constant temperature operation conditions, the focus is made on the molten salt solar tower due to its high storage capacity. Flow sheet has been elaborated and simulations have been carried out with the software Aspen Plus 8.4 for MW scaled-up hydrogen production plants. The solar part has been laid out with the software HFLCAL. Two different scenarios have been considered: the first one concerns the production of 400 kg/d hydrogen corresponding to a mobility scenario. The second scenario deals with the production of 4000 kg/d hydrogen for an industrial use. The process has been analyzed from a thermodynamic point of view by calculating the overall process efficiency. Taking into account the storage and a steam to hydrogen conversion of 50%, the process efficiency was calculated at 14% and the solar efficiency at 59.2%.

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  • Hydrogen production by coupling pressurized high temperature electrolyser with solar tower technology

    N. Monnerie;A. Houaijia;M. Roeb;C. Sattler;

    World hydrogen energy conference

    2016年

  • All Japan Hydrogen Project to Realize Hydrogen Economy

    作者:Y. Kojima;H. Takagi;M. Harada;N. Kuriyama;K Sakata;H. Kameyama;H. Uchida; 会议名称:World hydrogen energy conference 2016年

    Based on energy and environmental issues, we have a transportation fuel crisis and negative effects of global warming such as sea level rise and abnormal weather etc. Figure 1 shows global CO_2 emissions pathways reported by Intergovernmental Panel on Climate Change (IPCC). In order to achieve 2°C global temperature change limit target above pre-industrial level, it is necessary to reduce CO_2 emissions around 40-70% by 2050 compared to the level in 2010, and almost zero emission by 2100.

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  • All Japan Hydrogen Project to Realize Hydrogen Economy

    Y. Kojima;H. Takagi;M. Harada;N. Kuriyama;K Sakata;H. Kameyama;H. Uchida;

    World hydrogen energy conference

    2016年

  • Fossil fuel-based production of hydrogen with low-to-zero CO_2 emissions: Overview of technologies

    作者:N. Muradov; 会议名称:World hydrogen energy conference 2016年

    Currently, practically all industrial manufacturing of hydrogen is based on fossil fuels. However, even the "cleanest" of H_2 production processes, steam methane reforming (SMR), produces close to 10 kg CO_2 per kg H_2 product. Therefore, there is an urgent need to develop and implement fossil fuel-based hydrogen production processes with low-to-zero CO_2 emissions. The objective of this paper is to analyze existing and emerging technological options for eliminating or drastically reducing the amount of CO_2 emissions from fossil fuel-based hydrogen production plants. The main approaches to low-to-zero CO_2 production of hydrogen from fossil fuels are: 1.the integration of fossil fuel-based hydrogen plants with CO_2 capture and storage, 2.production of CO_2-free hydrogen via dissociation of methane, and 3.the integration of fossil fuel-based hydrogen production processes with non-carbon energy sources such as nuclear and solar. Current status and outlook for low-carbon production of hydrogen from fossil fuels are discussed in this paper.

    关键字:

  • Fossil fuel-based production of hydrogen with low-to-zero CO_2 emissions: Overview of technologies

    N. Muradov;

    World hydrogen energy conference

    2016年

  • Fuel cells in the aeronautical sector

    作者:M.P. Argumosa; 会议名称:World hydrogen energy conference 2016年

    Fuel Cells as power source is a promising and versatile technology. Its use in the transport sector has been largely demonstrated in the last 15 years, and now Fuel cell cars are commercially available. Fuel cells on aerospace application have also been developed in several space missions; but what about the aeronautical sector? Have already been proved this technology in this market or there are some handicaps to success in it?

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  • Fuel cells in the aeronautical sector

    M.P. Argumosa;

    World hydrogen energy conference

    2016年

  • LCA of Power to Transport chains and the different role of hydrogen

    作者:J.C. Koj;J. Linssen;A. Schreiber;C. Wulf;P. Zapp; 会议名称:World hydrogen energy conference 2016年

    Transportation is an important sector for economy and prosperity worldwide. It is one of the backbones of society and economic welfare. This is the shiny side of the medal. The dark sides are greenhouse gas (GHG), nitrogen oxides and particulate matter emissions as well as noise threatening people especially in urban areas plus the consumption of exhaustible resources. Therefore, future sustainable transport systems have to be based on renewable, efficient and climate/ environment/ health friendly energy sources. The enlarged use of electricity in transportation and especially electric or hydrogen vehicles as new flexible electricity consumers for excess wind power is of interest in renewable energy (REN) dominated energy systems. From this starting point the question arises which Power to Transport option is the most environmentally friendly one.

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  • LCA of Power to Transport chains and the different role of hydrogen

    J.C. Koj;J. Linssen;A. Schreiber;C. Wulf;P. Zapp;

    World hydrogen energy conference

    2016年

  • Experimental Study on Totalized Hydrogen Energy Utilization System using Wind Power Data

    作者:Satya Sekhar Bhogilla;Hiroshi Ito;Atsushi Kato;Akihiro Nakano; 会议名称:World hydrogen energy conference 2016年

    The global energy consumption has been increasing steadily due to the rapid industrialization and improvement in the living standard of the mankind. The predominant part of power is still produced from the fossil fuels. But, these fuel resources are limited and thus the mankind is forced to find the alternatives for resolving the critical issues associated with the use of fossil fuels such as environmental pollution and global warming. Clean and ecologically benign energy sources are imperative for the sustainable global economic growth. The vision for a clean, abundant, safe, affordable and reliable form of energy needs to be realized for the harmonious existence of life on earth. A number of renewable energy sources such as solar energy, wind energy, geothermal energy, tidal energy, etc. are generating significant wattage, but most of these resources are intermittent power sources that researchers must find ways to store the fluctuating power generated from the renewable energy sources. Hydrogen has several attractive characteristics to be an ideal energy carrier for future, because it is renewable and can be produced from or converted to other energy forms at high efficiency. Hydrogen has a high gravimetric energy density can be stored for long period of time without energy loss. Hydrogen based energy storage system represents an important option to store the fluctuating power generated from the renewable sources. The focus on stand-alone renewable energy systems is highlighted by many researchers [1-5]. The Totalized Hydrogen Energy Utilization System (THEUS) consists of the Unitized Reversible Fuel Cell (URFC), which has both Fuel Cell (FC) and water electrolysis functions in one component, Metal Hydride Tank (MHT), and their auxiliary components. The main objective of this paper is to evaluate the T HEUS operation and performance at different variations in wind power and to characterize its dynamic response. Energy efficiehcy of the THEUS was evaluated in Water Electrolyzer (WE) and FC mode operation.

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  • Experimental Study on Totalized Hydrogen Energy Utilization System using Wind Power Data

    Satya Sekhar Bhogilla;Hiroshi Ito;Atsushi Kato;Akihiro Nakano;

    World hydrogen energy conference

    2016年

  • Study of the influence of the balance of plant and key parameters on the performance of an alkaline water electrolyzer

    作者:M. Sanchez;E. Amores;B. Oraa; 会议名称:World hydrogen energy conference 2016年

    The main objective of this paper is the study and optimization of several key parameters of the balance of plant (BoP) that constitutes an alkaline electrolyzer. Particularly, the paper focuses on analyzing the influence of the gas-electrolyte separators design and on determining the critical parameters of operation, in order to establish certain design - basis for such systems. Moreover, a mathematical model is developed for the polarization curve with the aim of predicting the system behavior under different operating conditions.

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  • Study of the influence of the balance of plant and key parameters on the performance of an alkaline water electrolyzer

    M. Sanchez;E. Amores;B. Oraa;

    World hydrogen energy conference

    2016年

  • RENOVAGAS: process for the production of renewable natural gas

    作者:J. Rubio;P.Cortes;M.T. Escudero;I. de Godos;J.A, Lana;R. Navarro;S. Perez;M. Sanchez; 会议名称:World hydrogen energy conference 2016年

    The energy supply of the future will implement renewable sources to a greater extent as today. Increasing use of renewable energy, particularly wind and solar power, causes local discrepancies between supply and demand in the power grid because their extremely variability. These discrepancies can produce failures on the electricity grid and measures to absorb them, as electricity storage systems, are needed.

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  • RENOVAGAS: process for the production of renewable natural gas

    J. Rubio;P.Cortes;M.T. Escudero;I. de Godos;J.A, Lana;R. Navarro;S. Perez;M. Sanchez;

    World hydrogen energy conference

    2016年

  • Hydrogen systems: a wide panel of services to help manage the electric systems

    作者:B. Guinot;C. Mansilla; 会议名称:World hydrogen energy conference 2016年

    The energy transition to a low-carbon energy system involves the massive deployment of non-dispatchable renewable energy sources, such as wind and solar power. In such a context, the electric system that faces the challenge to balance injections and withdrawals on the network at all times, have diverse levers. Some of them act on the supply side, others on the demand side, and some —such as storage and interconnections- act on both. Hydrogen systems are part of the global picture.

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  • Hydrogen systems: a wide panel of services to help manage the electric systems

    B. Guinot;C. Mansilla;

    World hydrogen energy conference

    2016年

  • Composite Overwrapped Pressure Vessels resistance to mechanical impact - HYPACTOR Project (FCH JU 2014-2017)

    作者:F. Nony;N. Alexandre;O. Bardoux;P. Breuer;F. Dahmene;M. Barcikowski;K. Lasn;P. Lenain; 会议名称:World hydrogen energy conference 2016年

    Hydrogen is expected to be a highly valuable energy carrier for the 21st century as it should participate in answering main societal and economical concerns. However, in order to enable its extensive use as an energy vector, it is of primary importance to ensure its societal acceptance and thus its safety in use. To this aim, hydrogen storage and transportation must be secured. In particular today, the knowledge on composite overwrapped pressure vessels' (COPV) behaviour when submitted to mechanical impacts is limited and existing standards are not well-appropriate to composite materials.

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  • Composite Overwrapped Pressure Vessels resistance to mechanical impact - HYPACTOR Project (FCH JU 2014-2017)

    F. Nony;N. Alexandre;O. Bardoux;P. Breuer;F. Dahmene;M. Barcikowski;K. Lasn;P. Lenain;

    World hydrogen energy conference

    2016年

  • Scenario study for full-fledged hydrogen utilization with CO_2-free hydrogen global supply chains

    作者:M. Sasakura;Y. Ishimoto;K. Sakata; 会议名称:World hydrogen energy conference 2016年

    In April 2014, the Cabinet of Japan approved the new Strategic Energy Plan stating that it is essential for Japan to formulate a road map toward the realization of a "hydrogen society", considering the dramatic changes in energy environments inside and outside Japan, including the Great East Japan Earthquake on 11 March 2011 and the subsequent accidents at TEPCO's Fukushima Daiichi Nuclear Power Station[l]. In June 2014, in line with the new Strategic Energy Plan, the Council from industry, academia and government compiled views, goals and collaborative efforts into a road map with clear time frames attached[2].

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  • Scenario study for full-fledged hydrogen utilization with CO_2-free hydrogen global supply chains

    M. Sasakura;Y. Ishimoto;K. Sakata;

    World hydrogen energy conference

    2016年

  • Ni-CaO Combined Sorbent-Catalyst Materials usage for Sorption Enhanced Steam Methane Reforming

    作者:A. Di Giuliano;C. Courson;K. Gallucci;A. Kiennemann; 会议名称:World hydrogen energy conference 2016年

    In the aim to develop new low carbon power generation processes, energy efficiency can be improved by associating carbon dioxide capture. Our work concerns SE-SMR (Sorption Enhanced Steam Methane Reforming) looping cycle. It is based on solid particles of CSCMs (Combined Sorbent Catalyst Materials) constituted by CaO — for sorbent function — and a reforming catalyst (metallic state) on the same support. Main reactions are [1]: Methane Steam Reforming (MSR) CH_4(g) + H_2O_(v) → CO_(g) + 3H_(2(g)) □ H_(298K)~0 = 206.2 kJ/mol Water-gas shift (WGS) CO(g) + H_2O(v) □ CO_2(g) + H_(2(g)) □ H_(298K)~0=-41.2 kJ/mol CO_2 sorption CO_2(g) + CaO_(s)□ CaCO_(3(s)) □H_(298K)~0= - 178.2 kJ/mol The last reaction shifts to the right WGS equilibrium by removing gaseous CO_2, so H_2 gas fraction increases. All reactions occur on the same solid particle and the global process in nearly auto-thermal. The hypothesized process works with this sequence: SE-SMR proceeds by CSCM particles (650°C, 1 atm [2]); these are then regenerated by calcination (reverse of CO_2 sorption, 800-900 °C, 1 atm); regenerated particles then return to SEMSR conditions, starting a new cycle; high purity H_2 here produced can be converted in power by fuel cells.

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  • Ni-CaO Combined Sorbent-Catalyst Materials usage for Sorption Enhanced Steam Methane Reforming

    A. Di Giuliano;C. Courson;K. Gallucci;A. Kiennemann;

    World hydrogen energy conference

    2016年

  • Low temperature-high selectivity carbon monoxide methanation over yttria-stabilized zirconia-supported Pt nanoparticles

    作者:R. Isaifan;M. Couillard;E. Baranova; 会议名称:World hydrogen energy conference 2016年

    The high purity hydrogen, free from any traces of carbon monoxide is crucial for the efficient operation of hydrogen proton exchange membrane fuel cells (PEMFCs). In this work, we report the first study on the effect of particle size on the low temperature (25 — 120°C) carbon monoxide methanation in hydrogen-rich streams over Pt nanoparticles of four average particle sizes: 1.9, 3.0, 4.4 and 6.7 cm supported on ionically-conductive yttria-stabilized zirconia (Pt/YSZ). The results demonstrate that CO methanation is a strongly size sensitive reaction over Pt/YSZ with higher activity of the smaller nanoparticles. The turnover frequency at 60°C of CO methanation reaction rate increases by a factor of 9.7 with decreasing Pt/YSZ mean particle size from 6.7 to 1.9 nm.

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  • Low temperature-high selectivity carbon monoxide methanation over yttria-stabilized zirconia-supported Pt nanoparticles

    R. Isaifan;M. Couillard;E. Baranova;

    World hydrogen energy conference

    2016年

  • A Pore scale study on water distribution in porous media: Effects of hydrophobic and hydrophilic properties on fluid flow states

    作者:Gao Yuan; 会议名称:World hydrogen energy conference 2016年

    The carbon cloth gas diffusion layer (GDL) in Proton Exchange membrane Fuel Cell is a kind of porous system. The presence of solid particles in the porous system will causes the diffusion paths of species to deviate from straight lines.

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  • A Pore scale study on water distribution in porous media: Effects of hydrophobic and hydrophilic properties on fluid flow states

    Gao Yuan;

    World hydrogen energy conference

    2016年

  • Water buildup and evolution during the startup of a PEMFC:visualization by means of Neutron Imaging

    作者:A. Iranzo;P. Boillat;J.A. Salva;Biesdorf;E. Tapia;F. Rosa; 会议名称:World hydrogen energy conference 2016年

    A commercial 50 cm~2 PEM fuel cell with serpentine flow fields was operated at. 2.0 bara and 60 °C with different relative humidity values for the inlet reactants. Between each test the cell was decompressed and liquid water was thus flushed out. The liquid water build-up after each decompression was visualized by means of Neuron Imaging. The cell performance and operating data including cell voltage and resistance were measured, and neutron radiographs were recorded during the entire operation in order to gain knowledge about the liquid water distribution and evolution within the cell along the transient operation. A quantitative analysis of the results is presented in this work, comparing the cell operation for the different reactants inlet humidity.

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  • Water buildup and evolution during the startup of a PEMFC:visualization by means of Neutron Imaging

    A. Iranzo;P. Boillat;J.A. Salva;Biesdorf;E. Tapia;F. Rosa;

    World hydrogen energy conference

    2016年

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6.其他规定

(1)本协议内容受中华人民共和国法律的约束。如果本协议中任何规定被裁定为无效或不可强制执行,该项规定应被撤销,而其余规定继续有效。

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注意:六维联合未就您或其他人士的某项违约行为采取行动,并不表明六维联合就任何继后或类似的违约事件放弃采取行动的权利。


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