CN104745904B - 一种炼油厂用输油泵 - Google Patents

一种炼油厂用输油泵 Download PDF

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CN104745904B
CN104745904B CN201510199553.9A CN201510199553A CN104745904B CN 104745904 B CN104745904 B CN 104745904B CN 201510199553 A CN201510199553 A CN 201510199553A CN 104745904 B CN104745904 B CN 104745904B
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hours
incubated
pump housing
ceramic material
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CN104745904A (zh
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陈思
张小平
高龙
付伟锋
张燕
王顺利
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Fu Wei Feng
Gao Long
Guangdong Gaohang Intellectual Property Operation Co ltd
Wang Shunli
Zhang Xiaoping
Zhang Yan
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Abstract

一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,铝合金和铜合金的成分简单可以达到油泵的强度要求;对该成分的铝合金和铜合金进行酸洗及钝化的表面处理工序,避免出现任何表面黑点等问题,使获得表面整洁。

Description

一种炼油厂用输油泵
技术领域
本发明涉一种炼油厂用输油泵,属于炼油厂设备的制造技术领域。
背景技术
输油泵是的质量越发重要,它在使用中最易受到的损伤是腐蚀、磨损和砂卡等。输油泵的使用寿命也越来越短,输油成本逐年增加。为了延长输油泵的使用寿命,目前的解决办法是在输油泵泵筒内壁和柱塞外壁敷设分段的烧结类陶瓷套筒,这种改进虽然在耐磨、耐高温、耐腐蚀等性能比较出色,但是陶瓷套筒容易发生破碎、崩裂和错位等现象,而且抗冲击能力低,从而影响到输油泵的使用性能,不利于长时间输油作业。
发明内容
本发明所要解决的技术问题是提供一种防腐、耐磨、耐高温、成本低炼油厂用输油泵。
一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu:12-13﹪、Ni:10-11﹪、Si:7-8﹪、Zn:4-5﹪、Cr:1-2﹪、V:0.6-0.7﹪,Ti:0.4-0.5﹪、Mg:0.3-0.4﹪、Ce:0.07-0.08﹪、Zr:0.07-0.08﹪、Fe:0.05-0.06﹪,Mn :0.02-0.03﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度:770-780℃,浇注温度为720-725℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸20-30份,烷基咪唑啉季铵盐10-15份,丙酸5-6份,甲酸1-5份; 羟基乙酸1-2份,乙二胺1-2份、水100份;
钝化液组成为(重量):硫酸20-25份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷10-15份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷10-15份,聚酰亚胺1-5份,甲酸钠5-10份,氟硼酸钠1-5份,缓冲剂1-3份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆80-90份,氮化钛 50-60份,碳化钨10-20份,碳化铬10-15份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮。
铜合金泵体化学组成为(重量):Al:15-16﹪、Mg:10-12﹪、Si:5-6﹪、Zn:4-5﹪、Ti:0.8-0.9﹪、V:0.6-0.7﹪,Cr:0.3-0.4﹪、Fe:0.1-0.2﹪,Zr:0.07-0.08﹪、Y:0.05-0.06﹪、Ni 0.07-0.08﹪、Mn :0.03-0.04﹪,B:0.01-0.02﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸50-60份,36.5%的HCL 10-20份,烷基咪唑啉季铵盐5-6份,98%浓H2SO4 2-3份,乙二胺1-2份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷50-60份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷20-30份,硫酸10-15份,聚酰亚胺1-5份,氟硼酸钠1-5份,二烷基二硫代磷酸氧钼1-3份,水50-60份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬30-40份,氮化钛 10-15份,碳化硅5份,硼化钛1-3份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛10-20份,氮化钛5-10份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。
所述的一种炼油厂用输油泵,铝合金叶轮本体化学组成为(重量):Cu:12﹪、Ni:10﹪、Si:7﹪、Zn:4﹪、Cr:1﹪、V:0.6﹪,Ti:0.4﹪、Mg:0.3﹪、Ce:0.07﹪、Zr:0.07﹪、Fe:0.05﹪,Mn :0.02﹪,余量为Al以及不可避免的杂质。
所述的一种炼油厂用输油泵,铝合金叶轮本体化学组成为(重量):Cu: 13﹪、Ni:11﹪、Si: 8﹪、Zn: 5﹪、Cr: 2﹪、V: 0.7﹪,Ti: 0.5﹪、Mg: 0.4﹪、Ce: 0.08﹪、Zr:0.08﹪、Fe: 0.06﹪,Mn : 0.03﹪,余量为Al以及不可避免的杂质。
所述的一种炼油厂用输油泵,铝合金叶轮本体化学组成为(重量):Cu:12.5﹪、Ni:10.5﹪、Si:7.5﹪、Zn:4.5﹪、Cr:1.5﹪、V:0.65﹪,Ti:0.45﹪、Mg:0.35﹪、Ce:0.075﹪、Zr:0.075﹪、Fe:0.055﹪,Mn :0.025﹪,余量为Al以及不可避免的杂质。
所述的一种炼油厂用输油泵,碳化锆系陶瓷材料层包括(重量):碳化锆80份,氮化钛 50份,碳化钨10份,碳化铬10份,硼化钛10份。
所述的一种炼油厂用输油泵,碳化锆系陶瓷材料层包括(重量):碳化锆90份,氮化钛 60份,碳化钨20份,碳化铬15份,硼化钛10份。
所述的一种炼油厂用输油泵,碳化锆系陶瓷材料层包括(重量):碳化锆85份,氮化钛 55份,碳化钨15份,碳化铬13份,硼化钛10份。
所述的一种炼油厂用输油泵,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬30份,氮化钛 10份,碳化硅5份,硼化钛1份。
所述的一种炼油厂用输油泵,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬40份,氮化钛 15份,碳化硅5份,硼化钛3份。
所述的一种炼油厂用输油泵,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬35份,氮化钛 13份,碳化硅5份,硼化钛2份。
一种防腐、耐磨、耐高温、成本低炼油厂用输油泵及其制造方法,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu:12-13﹪、Ni:10-11﹪、Si:7-8﹪、Zn:4-5﹪、Cr:1-2﹪、V:0.6-0.7﹪,Ti:0.4-0.5﹪、Mg:0.3-0.4﹪、Ce:0.07-0.08﹪、Zr:0.07-0.08﹪、Fe:0.05-0.06﹪,Mn :0.02-0.03﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度:770-780℃,浇注温度为720-725℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸20-30份,烷基咪唑啉季铵盐10-15份,丙酸5-6份,甲酸1-5份; 羟基乙酸1-2份,乙二胺1-2份、水100份;
钝化液组成为(重量):硫酸20-25份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷10-15份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷10-15份,聚酰亚胺1-5份,甲酸钠5-10份,氟硼酸钠1-5份,缓冲剂1-3份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆80-90份,氮化钛 50-60份,碳化钨10-20份,碳化铬10-15份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮。
铜合金泵体化学组成为(重量):Al:15-16﹪、Mg:10-12﹪、Si:5-6﹪、Zn:4-5﹪、Ti:0.8-0.9﹪、V:0.6-0.7﹪,Cr:0.3-0.4﹪、Fe:0.1-0.2﹪,Zr:0.07-0.08﹪、Y:0.05-0.06﹪、Ni 0.07-0.08﹪、Mn :0.03-0.04﹪,B:0.01-0.02﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸50-60份,36.5%的HCL 10-20份,烷基咪唑啉季铵盐5-6份,98%浓H2SO4 2-3份,乙二胺1-2份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷50-60份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷20-30份,硫酸10-15份,聚酰亚胺1-5份,氟硼酸钠1-5份,二烷基二硫代磷酸氧钼1-3份,水50-60份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬30-40份,氮化钛 10-15份,碳化硅5份,硼化钛1-3份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛10-20份,氮化钛5-10份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。
所述泵体内表面为被传输介质通过泵内部时可以接触到泵体内部表面的部分,泵体其余部分为泵体外表面。
上述发明内容相对于现有技术的有益效果在于:1)铝合金和铜合金的成分简单可以达到油泵的强度要求;2)对该成分的铝合金和铜合金进行酸洗及钝化的表面处理工序,避免出现任何表面黑点等问题,使获得表面整洁;3)通过在铝合金和铜合金表面涂覆陶瓷材料,提高材料的防腐、耐磨、耐高温性能。
具体实施方式
为了对本发明的技术特征、目的和效果有更加清楚的理解,现详细说明本发明的具体实施方式。
实施例1
一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu:12﹪、Ni:10﹪、Si:7﹪、Zn:4﹪、Cr:1﹪、V:0.6﹪,Ti:0.4﹪、Mg:0.3﹪、Ce:0.07﹪、Zr:0.07﹪、Fe:0.05﹪,Mn :0.02﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度:770℃,浇注温度为720℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸20份,烷基咪唑啉季铵盐10份,丙酸5份,甲酸1份; 羟基乙酸1份,乙二胺1份、水100份;
钝化液组成为(重量):硫酸20份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷10份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷10份,聚酰亚胺1份,甲酸钠5份,氟硼酸钠1份,缓冲剂1份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆80份,氮化钛 50份,碳化钨10份,碳化铬10份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮。
铜合金泵体化学组成为(重量):Al:15﹪、Mg:10﹪、Si:5﹪、Zn:4﹪、Ti:0.8﹪、V:0.6﹪,Cr:0.3﹪、Fe:0.1﹪,Zr:0.07﹪、Y:0.05﹪、Ni 0.07﹪、Mn :0.03﹪,B:0.01﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸50份,36.5%的HCL 10份,烷基咪唑啉季铵盐5份,98%浓H2SO4 2份,乙二胺1份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷50份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷20份,硫酸10份,聚酰亚胺1份,氟硼酸钠1份,二烷基二硫代磷酸氧钼1份,水50份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬40份,氮化钛 15份,碳化硅5份,硼化钛3份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛10份,氮化钛5份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。
实施例2
一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu: 13﹪、Ni: 11﹪、Si: 8﹪、Zn: 5﹪、Cr: 2﹪、V: 0.7﹪,Ti: 0.5﹪、Mg: 0.4﹪、Ce: 0.08﹪、Zr: 0.08﹪、Fe:0.06﹪,Mn : 0.03﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度: 780℃,浇注温度为725℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸30份,烷基咪唑啉季铵盐15份,丙酸6份,甲酸5份; 羟基乙酸2份,乙二胺2份、水100份;
钝化液组成为(重量):硫酸25份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷15份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷15份,聚酰亚胺5份,甲酸钠10份,氟硼酸钠5份,缓冲剂3份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆90份,氮化钛 60份,碳化钨20份,碳化铬15份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮。
铜合金泵体化学组成为(重量):Al: 16﹪、Mg: 12﹪、Si: 6﹪、Zn: 5﹪、Ti:0.9﹪、V: 0.7﹪,Cr: 0.4﹪、Fe: 0.2﹪,Zr: 0.08﹪、Y: 0.06﹪、Ni 0.08﹪、Mn :0.04﹪,B: 0.02﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸60份,36.5%的HCL 20份,烷基咪唑啉季铵盐6份,98%浓H2SO4 3份,乙二胺2份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷60份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷30份,硫酸15份,聚酰亚胺5份,氟硼酸钠5份,二烷基二硫代磷酸氧钼3份,水50-60份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬40份,氮化钛 15份,碳化硅5份,硼化钛3份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛20份,氮化钛10份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。
实施例3
一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu:12.5﹪、Ni:10.5﹪、Si:7.5﹪、Zn:4.5﹪、Cr:1.5﹪、V:0.65﹪,Ti:0.45﹪、Mg:0.35﹪、Ce:0.075﹪、Zr:0.075﹪、Fe:0.055﹪,Mn :0.025﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度:775℃,浇注温度为723℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸25份,烷基咪唑啉季铵盐13份,丙酸5.5份,甲酸3份; 羟基乙酸1.5份,乙二胺1.5份、水100份;
钝化液组成为(重量):硫酸23份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷13份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷13份,聚酰亚胺3份,甲酸钠7份,氟硼酸钠3份,缓冲剂2份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆85份,氮化钛 55份,碳化钨15份,碳化铬13份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮。
铜合金泵体化学组成为(重量):Al:15.5﹪、Mg:11﹪、Si:5.5﹪、Zn:4.5﹪、Ti:0.85﹪、V:0.65﹪,Cr:0.35﹪、Fe:0.15﹪,Zr:0.075﹪、Y:0.055﹪、Ni 0.075﹪、Mn :0.035﹪,B:0.015﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸55份,36.5%的HCL 15份,烷基咪唑啉季铵盐5.5份,98%浓H2SO4 2.5份,乙二胺1.5份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷55份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷25份,硫酸13份,聚酰亚胺3份,氟硼酸钠3份,二烷基二硫代磷酸氧钼2份,水55份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬35份,氮化钛 13份,碳化硅5份,硼化钛2份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛15份,氮化钛7份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。
实施例4
一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu:12.2﹪、Ni:10.3﹪、Si:7.2﹪、Zn:4.3﹪、Cr:1.1﹪、V:0.64﹪,Ti:0.43﹪、Mg:0.32﹪、Ce:0.072﹪、Zr:0.071﹪、Fe:0.053﹪,Mn :0.022﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度:771℃,浇注温度为722℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸21份,烷基咪唑啉季铵盐11份,丙酸5.1份,甲酸2份; 羟基乙酸1.3份,乙二胺1.1份、水100份;
钝化液组成为(重量):硫酸21份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷11份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷11份,聚酰亚胺1.2份,甲酸钠6份,氟硼酸钠2份,缓冲剂1.1份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆82份,氮化钛 54份,碳化钨13份,碳化铬11份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮。
铜合金泵体化学组成为(重量):Al:15.2﹪、Mg:10.3﹪、Si:5.4﹪、Zn:4.4﹪、Ti:0.81﹪、V:0.62﹪,Cr:0.33﹪、Fe:0.11﹪,Zr:0.074﹪、Y:0.052﹪、Ni 0.073﹪、Mn :0.034﹪,B:0.012﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸52份,36.5%的HCL 13份,烷基咪唑啉季铵盐5.3份,98%浓H2SO4 2.1份,乙二胺1.2份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷51份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷23份,硫酸11份,聚酰亚胺2份,氟硼酸钠2份,二烷基二硫代磷酸氧钼1.1份,水52份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬32份,氮化钛 12份,碳化硅5份,硼化钛1.3份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛11份,氮化钛6份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。
实施例5
一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu:12.8﹪、Ni:10.9﹪、Si:7.9﹪、Zn:4.6﹪、Cr:1.6﹪、V:0.67﹪,Ti:0.48﹪、Mg:0.38﹪、Ce:0.077﹪、Zr:0.079﹪、Fe:0.056﹪,Mn :0.026﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度:777℃,浇注温度为724℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸29份,烷基咪唑啉季铵盐14份,丙酸5.8份,甲酸4份; 羟基乙酸1.8份,乙二胺1.7份、水100份;
钝化液组成为(重量):硫酸24份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷14份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷14份,聚酰亚胺4份,甲酸钠9份,氟硼酸钠4份,缓冲剂2.9份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆88份,氮化钛 57份,碳化钨18份,碳化铬14份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮。
铜合金泵体化学组成为(重量):Al:15.8﹪、Mg:11.7﹪、Si:5.8﹪、Zn:4.7﹪、Ti:0.87﹪、V:0.68﹪,Cr:0.38﹪、Fe:0.17﹪,Zr:0.079﹪、Y:0.059﹪、Ni 0.078﹪、Mn :0.036﹪,B:0.016﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸59份,36.5%的HCL 17份,烷基咪唑啉季铵盐5.6份,98%浓H2SO4 2.6份,乙二胺1.4份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷57份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷28份,硫酸14份,聚酰亚胺4份,氟硼酸钠4份,二烷基二硫代磷酸氧钼2.8份,水58份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬37份,氮化钛 14份,碳化硅5份,硼化钛2.8份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛17份,氮化钛9份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。

Claims (1)

1.一种炼油厂用输油泵,其包括一泵体和安装于所述泵体内部的叶轮,所述叶轮包括铝合金叶轮本体和叶轮本体外碳化锆系陶瓷材料层;泵体包括:铜合金泵体、泵体外表面的氧化铝系陶瓷材料层和泵体内表面的碳化硼系陶瓷材料层,
其特征在于,铝合金叶轮本体化学组成为(重量):Cu:12-13﹪、Ni:10-11﹪、Si:7-8﹪、Zn:4-5﹪、Cr:1-2﹪、V:0.6-0.7﹪,Ti:0.4-0.5﹪、Mg:0.3-0.4﹪、Ce:0.07-0.08﹪、Zr:0.07-0.08﹪、Fe:0.05-0.06﹪,Mn :0.02-0.03﹪,余量为Al以及不可避免的杂质;
铝合金叶轮本体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注:熔炼温度:770-780℃,浇注温度为720-725℃;脱模后,得到的叶轮进行热处理:首先将叶轮进行加热,升温至400℃,升温速率100℃/小时,保温7小时,后降温至300℃,降温速率20℃/小时,保温5小时,后升温至350℃,升温速率10℃/小时,保温3小时,后再次降温至200℃,降温速率75℃/小时,保温4小时,后再次降温至150℃,降温速率10℃/小时,保温5小时,后空冷至室温,
之后对叶轮表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取氢氟酸20-30份,烷基咪唑啉季铵盐10-15份,丙酸5-6份,甲酸1-5份; 羟基乙酸1-2份,乙二胺1-2份、水100份;
钝化液组成为(重量):硫酸20-25份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷10-15份, 2-(3,4-环氧环己基)乙基三甲氧基硅烷10-15份,聚酰亚胺1-5份,甲酸钠5-10份,氟硼酸钠1-5份,缓冲剂1-3份,水200份;
对钝化后叶轮外表面进行涂覆碳化锆系陶瓷材料;通过涂覆在叶轮外表面形成碳化锆系陶瓷材料层,碳化锆系陶瓷材料层厚度0.6mm,碳化锆系陶瓷材料层包括(重量):碳化锆80-90份,氮化钛 50-60份,碳化钨10-20份,碳化铬10-15份,硼化钛10份,将涂覆后的叶轮进行加热,升温至400℃,升温速率50℃/小时,保温6小时,后降温至300℃,降温速率50℃/小时,保温5小时,后再次降温至200℃,降温速率25℃/小时,保温7小时,后空冷至室温,得到最终叶轮,
铜合金泵体化学组成为(重量):Al:15-16﹪、Mg:10-12﹪、Si:5-6﹪、Zn:4-5﹪、Ti:0.8-0.9﹪、V:0.6-0.7﹪,Cr:0.3-0.4﹪、Fe:0.1-0.2﹪,Zr:0.07-0.08﹪、Y:0.05-0.06﹪、Ni:0.07-0.08﹪、Mn :0.03-0.04﹪,B:0.01-0.02﹪,余量为Cu以及不可避免的杂质;
铜合金泵体制备方法:包括以下步骤:按照上述比例配制合金,合金材料熔炼、浇注;脱模后,得到的泵体进行热处理:首先将泵体进行加热,升温至600℃,升温速率50℃/小时,保温4小时,后降温至400℃,降温速率75℃/小时,保温5小时,后升温至550℃,升温速率100℃/小时,保温6小时,后再次降温至350℃,降温速率75℃/小时,保温8小时,后再次降温至150℃,降温速率30℃/小时,保温7小时,后空冷至室温,
之后对泵体表面进行酸洗和钝化处理,其中:
酸洗液组成为(重量):采取丙酸50-60份,36.5%的HCL 10-20份,烷基咪唑啉季铵盐5-6份,98%浓H2SO4 2-3份,乙二胺1-2份、水300份;
钝化液组成为(重量):2-(3,4-环氧环己基)乙基三甲氧基硅烷50-60份,N-(2-氨基乙基)-3-氨基丙基甲基二甲氧基硅烷20-30份,硫酸10-15份,聚酰亚胺1-5份,氟硼酸钠1-5份,二烷基二硫代磷酸氧钼1-3份,水50-60份;
对钝化后泵体外表面进行涂覆氧化铝系陶瓷材料;通过涂覆在泵体外表面形成氧化铝系陶瓷材料层,氧化铝系陶瓷材料层厚度0.6mm,氧化铝系陶瓷材料层包括(重量):氧化铝100份,碳化铬30-40份,氮化钛 10-15份,碳化硅5份,硼化钛1-3份,将涂覆后的泵体进行加热,升温至700℃,升温速率150℃/小时,保温6小时,后降温至500℃,降温速率50℃/小时,保温5小时,后再次降温至300℃,降温速率75℃/小时,保温10小时,后空冷至室温,
之后对泵体内表面进行涂覆碳化硼系陶瓷材料;通过涂覆在泵体内表面形成碳化硼系陶瓷材料层,碳化硼系陶瓷材料层厚度0.5mm,碳化硼系陶瓷材料层包括(重量):碳化硼70份,碳化钛10-20份,氮化钛5-10份,碳化铬5份,将涂覆后的泵体进行加热,升温至600℃,升温速率100℃/小时,保温3小时,后降温至500℃,降温速率50℃/小时,保温6小时,后再次降温至300℃,降温速率50℃/小时,保温10小时,后空冷至室温,得到最终泵体。
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