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CN1507413A - 通过改良催化剂组合物的转化 - Google Patents

通过改良催化剂组合物的转化 Download PDF

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CN1507413A
CN1507413A CNA028095340A CN02809534A CN1507413A CN 1507413 A CN1507413 A CN 1507413A CN A028095340 A CNA028095340 A CN A028095340A CN 02809534 A CN02809534 A CN 02809534A CN 1507413 A CN1507413 A CN 1507413A
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R・G・西尔弗
R·G·西尔弗
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Abstract

用于一燃料电池(12)的一燃料处理子系统(14,16,18)中的转化器(16)使用一经改良的催化剂组合物(50)以减少用于该燃料电池(12)的过程气体中的一氧化碳量。催化剂组合物(50)是一贵金属催化剂,其具有一混合金属氧化物促进化载体,该混合金属氧化物至少包括二氧化铈和氧化锆两者。铈的含量介于30至50摩尔%之间,且锆的含量介于70至50摩尔%之间。其中亦可含有其他金属氧化物。使用该催化剂组合物(50)可避免预先还原催化剂的需要,且可尽量减少作业及/或停机期间为避免催化剂氧化所需采取的措施。

Description

通过改良催化剂组合物的转化
技术领域
本发明涉及碳氢化合物燃料处理,且具体而言涉及一经改良的转化器及其中所用的催化剂。更具体而言,本发明涉及用于处理富氢气流(其用于燃料电池)的转化器中及其中所用的经改良的催化剂组合物。
发明背景
利用一燃料电池组由碳氢化合物燃料产生电能的燃料电池发电厂已为我们所熟知。为使碳氢化合物燃料可用于燃料电池组作业中,其必须首先转化为富氢流。燃料电池组所使用的碳氢化合物燃料通过一重整方法以产生一氢含量增加的过程气体,该气体被引入该燃料电池组中。所得过程气体主要包括水、氢气、二氧化碳及一氧化碳。该过程气体自该重整器排出时含有约10%的一氧化碳(CO)。
高含量一氧化碳可引起作为燃料电池组一部分的阳极电极“中毒”。因而,必须在过程气体流至燃料电池组前减少其中之CO量。该目的通常在过程气体流至燃料电池组前使其通过一转化器且可能通过额外反应器(例如一选择性氧化器)来达成。该转化器亦可增加过程气体中氢气的产率。
用于减少过程气体中CO含量的转化器已为我们所熟知,且其通常包含一室,该室具有一用于使过程气体进入该室的入口、一位于该入口下游用于自该室排出排放物的出口及一位于该入口与出口之间的催化反应区。该催化反应区通常含有用于将过程气体中至少部分一氧化碳转化为二氧化碳的催化剂或催化剂组合物。在作业中,转化器发生放热转化反应,其由下式表示:
(1)
CO与水之间的反应(1)可同时使过程气体中的CO含量减少并使CO2和H2含量增加。该反应产生的额外氢气可有利于发电厂,因为燃料电池阳极消耗氢气以产生电能。对于一此类转化器的论述包含于关于“转化器”的PCT申请案第US97/08334号中(其以WO97/44123于1997年12月7日公开)。在该申请案的转化器中,一催化剂床包含由铜及氧化锌或铜、氧化锌及氧化铝构成的催化剂组合物。该催化剂组合物进一步揭示于颁予Kristiansen之美国专利第4,308,176号中,且其已多年用于促进燃料电池发电厂配套转化器中的转化反应。然而,使用该等催化剂组合物之反应器受限于其必须用氢气流吹扫以将其初步还原,且作业后必须采取若干步骤以防止其显著氧化或暴露于氧气。事实上,除非还原该催化剂,否则,所需反应并不进行或发生。该等催化剂组合物暴露于氧气对(或可能对)该催化剂不利。这是因为催化剂在氧气存在时会自加热,且其可易于将自身加热至使催化剂颗粒烧结的温度,并因而损失表面积并降低活性。该提供一还原氛围并在停机期间采用特殊停机吹扫同时保持惰性氛围以使氧气泄漏于该催化剂的可能性降至最低之需要会导致需考虑额外硬件及过程控制等方面的问题,从而会增加燃料电池发电厂系统特别是在转化器方面的复杂性及成本。
最近研究表明,铈氧化物或“二氧化铈”(CeO2)可与一贵金属联合用以促进转化反应并消除还原催化剂的需要。铈与铂组合可形成比先前催化剂更耐氧的催化剂。然而,该等二氧化铈促进化铂催化剂尚未在一适当尺寸的反应器的转化反应中表现出足够活性。相反,需要一过大的催化剂床,对于移动式燃料电池发电厂而言尤其如此。此外,通常水-气转化反应中的水含量可促使二氧化铈载体的烧结。
本发明可提供一含有一经改良之催化剂组合物的转化器,以利用水-气转化反应有效地将一氧化碳转化为二氧化碳并产生氢气,且不需特殊的催化剂预处理。本发明可进一步提供并使用一经改良活性增加的催化剂组合物于一转化反应器中,以利用水-气转化反应将一氧化碳转化为二氧化碳并产生氢气,且不需采取措施防止该催化剂暴露于空气。本发明可进一步提供并使用一经改良的催化剂组合物,其相对于水-气转化反应所用的现有贵金属催化剂而言具有经改良之活性及耐久性。
发明概述
一用于减少过程气体中一氧化碳量的转化器(用于燃料电池发电厂)使用一根据本发明之经改良的催化剂组合物。该转化器包括一用于使过程气体进入的入口、一位于该入口下游用于自室中排出排放物的出口及一位于该入口与出口之间的催化反应区。本发明的催化剂组合物位于转化器的催化反应区并可有效将过程气体中至少部分一氧化碳及水转化为二氧化碳及氢气。转化器使用经改良之催化剂组合物之作业可避免先前需预还原催化剂、提供特殊的停机后吹扫并在停机期间保持惰性氛围的要求。
用于转化器中的经改良之催化剂组合物包含一贵金属催化剂,其具有促进化载体,该促进化载体包含至少由铈氧化物(二氧化铈)和锆氧化物(氧化锆)组成的混合金属氧化物。同时含有氧化锆及二氧化铈促进剂可增加氧空穴量,并因而可增加该组合物的活性。此外,氧化锆可增强二氧化铈的抗烧结性,因而可提高该催化剂组合物的耐久性。该混合金属氧化物中除二氧化铈和氧化锆外亦可包括一选自由氧化镨、氧化镧、氧化钕及氧化铪组成之群的第三金属氧化物以形成金属氧化物的三元混合物。此外,可将氧化铝添加至该催化剂组合物(尤其当后者为粉末形式时)中以使其洗涂于一支持基材的适宜性提高。
该促进化载体上的贵金属催化剂可选自周期表中第二及第三过渡系列的VIIb、VIII及Ib族金属,通常以铂、钯、铑及金为佳,且以铂尤佳。
本发明进一步包括通过利用一转化器(其使用经改良之催化剂组合物)自用于燃料电池的方法燃料气体中除去一氧化碳的方法。
借助于对下述本发明例示性实施例(如附图所示)的详细阐释可更加清楚地了解本发明之上述及其他特征及优点。
附图说明
图1为一代表性燃料电池发电厂的简化功能示意图,其描述了一使用根据本发明的经改良之催化剂组合物的转化器。
图2为一描述本发明之经改良催化剂的转化活性与先前所用Cu/ZnO催化剂的转化活性之间的关系的图形。
本发明的优选实施方式
参照图1,其以功能示意图形式描述了一燃料电池发电厂10。该发电厂10包括一具有传统设计及构造的燃料电池组总成12及一燃料处理子系统,该子系统包括一重整器14、一转化器16及视情况一选择性氧化器18。该燃料处理器将碳氢化合物燃料源转化为富氢燃料流,其作为燃料供给燃料电池组总成12。通常,碳氢化合物燃料源是一液体(例如汽油)或气体(例如甲烷、天然气或其类似物),其被供给重整器14的燃料入口20。空气及/或蒸汽供给重整器14的空气/蒸汽入口22。重整器14以一习知方式使碳氢化合物燃料和蒸汽及/或空气反应以重整该碳氢化合物(和蒸汽)以产生氢气(H2)、一氧化碳(CO)、二氧化碳(CO2)和残余蒸汽/水(H2O)。然而,为进一步减少或最小化一氧化碳(CO)的含量(否则会使燃料电池组总成的阳极“中毒”),并增加用于燃料电池组总成1 2的富氢燃料源中氢气的产率,自重整器14排放的过程气体经导管24引导至转化器16,其在此经处理以将一氧化碳重整为二氧化碳。
转化器16可进行上述发明背景中式(1)所示的放热转化反应。我们期望转化器16中的反应是一氧化碳和水转化为二氧化碳和氢气的反应。根据需要,,亦可视情况提供一选择性氧化器18,其接收通过导管26自转化反应器16排出的过程气体,以通过添加空气(O2)进一步将一氧化碳转化为二氧化碳。所得排放气流含有足够丰富的氢气并耗尽一氧化碳以满足燃料电池组总成12的需要,且其经导管30引至燃料电池组总成12。
转化器16包括一壳体,其具有一催化剂室32,该催化剂室包含一或多个催化剂床或功能等效结构34,以促进所期望的转化反应。来自重整器14的过程气体通过入口36进入转化反应器16,流经并穿过催化剂室32中的催化剂床34,并经出口38排出。每一催化剂床34均包含一经调配特别适用于提高根据本发明的转化器16的性能的催化剂组合物(或简称为催化剂)50。尽管本文将催化剂50描述为催化剂室32内的一床,应了解,其他用于支持催化剂室32内的催化剂50的布置已为我们所熟知且其作为替代涵盖于本发明中。举例而言,一较佳布置可为一陶瓷、氧化铝、堇青石(氧化铝/氧化镁/氧化硅)及其类似物的蜂窝型结构,其安装于催化剂室32中且包含该催化剂作为其上之涂层。
催化剂50是位于混合金属氧化物促进化载体上的贵金属调配物,其中,至少两种金属氧化物为铈氧化物(或二氧化铈)(CeO2)和锆氧化物(或氧化锆)(ZrO2)。文献表明,二氧化铈作为氧空穴源可促进贵金属催化剂用于水-气转化反应。增加氧空穴被认为对应于改良水-气转化反应速度。更重要的是,已发现将一或多种其他金属氧化物(其中较重要的是氧化锆)添加至二氧化铈以产生一用于贵金属的混合金属氧化物促进化载体(即该载体是促进剂)可使所得催化剂组合物50在转化器16的较高作业温度(400-700°F)(204-371℃)下的抗烧结性增强,并进一步增加促进化催化剂的氧空穴量。
该催化剂组合物中二氧化铈和氧化锆的存在量彼此相互介于约50.0至30.0摩尔%(摩尔百分比)锆至50.0至70.0摩尔%(摩尔百分比)铈之间。第三金属氧化物的存在量可介于总氧化物的0.0至10.0摩尔%之间。贵金属可介于0.1至2.0摩尔%之间,一代表性实例中的值为0.3摩尔%。锆的量不应低于30.0%以保证其可使催化剂50具有增强的稳定性,且亦不应大于50.0%以防止系统中仅存在氧化锆相及/或二氧化铈相。
下文实例中给出了用于转化器16的催化剂组合物50所用的或其中所含的例示性调配物,其中MEI 01023粒料是二氧化铈和氧化锆的金属氧化物混合物,其作为贵金属催化剂的催化剂载体。该贵金属催化剂是铂。该颗粒中二氧化铈的含量为58摩尔%Ce,且氧化锆的含量为42摩尔%Zr。MEI 01023可自Magnesium Elektron Inc.(Flemington,New Jersey)购得。二氧化铈和氧化锆的促进化载体材料MEI 01023以直径为1/16英寸的小颗粒形式提供,但亦可以粉末或其类似形式提供。下述实例使用微湿法将铂涂敷于载体上。施于贵金属的其他方法亦为我们所熟知。
实例
载体                                 36.600克颗粒(50cc)
孔体积                               0.700克水/克催化剂
溶液量                               25.620克含Pt的溶液(见下
                                     文)填充颗粒的所有孔
Pt量
二氨基二硝酸铂-61%Pt(已标记)0.247   Pt/Pt(NH3)2(NO3)2
的量
Pt溶液
Pt(NH3)2(NO2)2          0.247
去离子水                     15.372
硝酸                         10.248
步骤:
1、称重并在212°F(100℃)下干燥该颗粒载体(MEI 01023)2小时。
2、将Pt(NH3)2(NO2)2溶解于10.248毫升上述浓硝酸中,持续搅拌。
3、一旦Pt溶解,即将Pt酸溶液加至该去离子水中。
4、将所得溶液倾倒于干燥颗粒上,然后用玻璃或Teflon®搅拌器搅拌,直到载体已经涂布均匀为止。
5、在212°F(100℃)下干燥所得混合物1小时,然后在752°(400℃)下煅烧4小时。
6、称重经干燥及煅烧的混合物,以获得/确定总质量差。
该调配物使用二氧化铈和氧化锆颗粒,并用铂涂布。所得经干燥和煅烧的混合物即催化剂组合物50。
或者,可将混合金属氧化物粉末洗涂于氧化铝或堇青石或此类适当载体基材上,然后,铂可以类似于制备该等颗粒的方式涂敷至经洗涂的载体上。此外,人们亦可希望将氧化铝添加至该粉末中以增强其洗涂于一支持基材的适宜性。该氧化铝可促进该洗涂层附着于载体基材。
图2是一阿累尼乌斯曲线图,其展示了根据上述实例制备的催化剂组合物50的转化活性,并以图形方式与先前在该水-气转化反应之转化反应器中用作催化剂的铜/锌氧化物催化剂颗粒之转化活性进行了比较。沿y轴的对数测量参数是水-气转化反应在给定温度下的反应速度常数k。沿x轴的线性测量参数是测量反应性时的温度的倒数,或1000/T。可以看出,当温度自300°F(149℃)增加至约400°F(204℃)时,先前技艺中所用的Cu/ZnO可使反应速度以第一斜率增加,随后,当温度自400°F(204℃)进一步增加至约600°F(316℃)时,反应速度以一更低的第二斜率增加。然而,应注意,当温度自约380°F(193℃)增加至600°F(316℃)时,本发明之CeO2/ZrO2催化剂上的Pt可使其反应速度以一基本恒定的斜率(与上述第一斜率相比)增加。在约580°F(364℃)至600°F(315℃)的交叉区域可观察到,本发明的催化剂组合物所展现的活性与Cu/ZnO的活性相等。因而,对于该等活性度,利用本发明贵金属催化剂50的反应器可具有与使用传统Cu/ZnO催化剂的反应器近似相等的尺寸,且不会使当前与后者配套的还原/吹扫/惰性系统的成本、体积及复杂性增加。
尽管氧化锆是含二氧化铈混合物中的第二金属氧化物,但可通过包含第三金属氧化物于该等氧化物的三元混合物中来获得其他优点(例如更低的总成本)。该第三金属氧化物可方便的选自由氧化镨、氧化镧、氧化钕及二氧化铪组成之群。加入一或多种该等金属氧化物可有助于ZrO2的稳定化及二氧化铈的促进化。
包含由至少二氧化铈及氧化锆的混合金属氧化物支持的催化剂的贵金属或该等金属可选自周期表中第二及第三过渡系列的VIIb、VIII及Ib族金属。该族贵金属包括铼、铂、钯、铑、钌、锇、铱、银及金。通常以铂、钯、铑及/或金(单独或组合)较佳,且铂是尤佳之贵金属。铂较佳是因为其可提供所需活性度以在合适尺寸/体积的反应器中获得期望的反应速度。

Claims (12)

1.一种用于减少水气转化反应中所用过程气体(20,24)中一氧化碳量的转化器(16),该转化器(16)具有一催化剂室(32),该催化剂室(32)具有一用于使过程气体进入该室的入口(36)、一位于该入口下游用于自该室排出排放物的出口(38)及一位于该入口(36)与该出口(38)之间用于将该过程气体中至少部分一氧化碳和水转化为二氧化碳和氢气的催化剂组合物(50),催化剂室(32)中的催化剂组合物(50)的改良包括:
一具有促进化载体的贵金属催化剂,该促进化载体包括至少铈氧化物(二氧化铈)和锆氧化物(氧化锆)的混合金属氧化物。
2.如权利要求1所述的转化器(16),其中该混合金属氧化物中的铈含量介于30至50摩尔%之间且锆的存在量介于70至50摩尔%之间。
3.如权利要求1所述的转化器(16),其中该催化剂组合物(50)中的贵金属选自铂、钯、铑和金。
4.如权利要求3所述的转化器(16),其中该催化剂组合物(50)中的贵金属是铂。
5.如权利要求1所述的转化器(16),其中该包括该促进化载体的金属氧化物另外包括至少一第三金属氧化物。
6.如权利要求5所述的转化器(16),其中该第三金属氧化物选自氧化镨、氧化镧、氧化钕和二氧化铪。
7.如权利要求1所述的转化器(16),其中至少该催化剂组合物(50)的促进化载体被洗涂于一载体基材上,且进一步包含与该促进化载体混合的氧化铝以促进该洗涂层附着于该载体基材上。
8.如权利要求1所述的转化器(16),其中该催化剂组合物(50)的使用不受任何预还原、停机清扫或惰性气氛要求的限制。
9.如权利要求1所述的转化器(16),其中该转化器(16)可有效连接于一用于燃料电池(12)的燃料处理子系统(14,16,18)。
10.如权利要求8所述的转化器(16),其中该转化器(16)可有效连接于一用于燃料电池(12)的燃料处理子系统(14,16,18)且该过程气体包括氢气。
11.减少用于燃料电池(12)的方法燃料气体中一氧化碳量的方法,其包括以下步骤:
a.将具有促进化载体的贵金属催化剂的催化剂组合物(50)置于一转化器(16)中,该促进化载体包括至少二氧化铈和氧化锆的混合金属氧化物;及
b.使该方法燃料气体有效接近该催化剂组合物(50)以通过一水-气转化反应将该方法燃料气体中至少部分一氧化碳转化为二氧化碳并产生氢气。
12.如权利要求11所述的方法,其中该催化剂组合物(50)可避免任何与该转化器(16)的作业有关的预还原、停机清扫或惰性气氛的需要。
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