ASTM A967-2001 不锈钢零件化学钝化处理的标准规范

不锈钢酸洗与钝化处理规范不锈钢酸洗与钝化处理规范1前言不锈钢设备由于接触到腐蚀性介质，会造成设备表面有明显的腐蚀痕迹及颜色不均匀的斑痕，因此对不锈钢设备表面的处理尤为关键，不锈钢设备表面的钝化处理就是一个重要环节。

设备表面钝化膜形成不完善，与铁离子接触造成污染，在使用过程中就会出现锈蚀现象，造成运行介质指标变化等。

下面就奥氏体不锈钢设备表面的酸洗钝化处理原理及实际操作的常规工艺过程谈一些看法，以供有关人员参考。

2 概述奥氏体不锈钢具有良好的耐腐蚀性能，而且还有良好的冷热加工性能，因此被广泛地用于制造各类具有防腐蚀要求的压力容器，奥氏体不锈钢表面的钝化膜，对其耐腐蚀有很大影响。

奥氏体不锈钢的钝化膜主要是通过对其表面进行酸洗钝化处理得来的。

3 酸洗钝化的原理3.1钝化：金属经氧化性介质处理后，其腐蚀速度比原来未处理前有显著下降的现象称金属的钝化。

其钝化机理主要可用薄膜理论来解释，即认为钝化是由于金属与氧化性介质作用，作用时在金属表面生成一种非常薄的、致密的、覆盖性能良好的、能牢固地附在金属表面上的钝化膜。

这层膜成独立相存在，通常是氧和金属的化合物。

它起着把金属与腐蚀介质完全隔开的作用，防止金属与腐蚀介质直接接触，从而使金属基本停止溶解。

奥氏体不锈钢经氧化性介质处理后其表面能形成满足上述要求的钝化膜，但该钝化膜在起活化作用的Cl-、Br-、F-等卤素离子作用下，极易受到破坏。

这也就是虽经酸洗钝化处理的奥氏体不锈钢压力容器在进行水压试验后若不能将水渍除干净，但应控制水的Cl-含量不超过25ppm的原因之一。

另外并非任何金属的氧化膜都可视作钝化膜，如碳钢在高温氧化后形成的氧化膜由于不能满足牢固地附在金属表面的要求而不能充作钝化膜。

3.2 对于奥氏体不锈钢一般采用氧化性强的以硝酸为主剂的溶液来进行处理，为确保钝化处理的效果，在钝化前先对被钝化表面进行酸洗处理。

整个处理过程就称为酸洗钝化处理，简称酸洗钝化。

4 酸洗液、钝化液及酸洗膏配方酸洗液：20%硝酸+5%氢氟酸+75%水钝化液：5%硝酸+2%重铬酸钾十93%水酸洗钝化液(二合一)：20%硝酸+10%氢氟酸+70%水酸洗钝化膏(二合一)配方：盐酸20毫升，水100毫升，硝酸30毫升，澎润土150克搅拌成糊状。

不锈钢酸零部件膏剂酸洗钝化工艺规程说明：不锈钢零部件在制造过程中，经过运输、划线、下料成型及焊接，每道工序只要稍不注意，最后在零部件表面会留下划伤、划痕、榔头印痕迹等。

使零部件抗腐蚀性能降低，直接影响使用寿命。

为提高不锈钢零部件抗腐蚀能力，延长产品使用寿命，因此对不锈钢零部件必须进行酸洗、钝化表面处理，为控制零部件表面质量，特制定本工艺规程。

本工艺规程，仅适用于涂刷膏剂进行酸洗、钝化的不锈钢零部件。

1.对产品酸洗零部件表面质量要求：1.1焊缝表面熔渣，焊接飞溅必须去除干净。

1.2钢板表面严重划伤，砂轮磨痕应用细砂轮打磨干净，然后用抛光机进行局部抛光。

1.3钢板表面不得有明显的凹坑。

2.表面处理（酸洗、钝化）工艺流程：去灰尘（用冷水冲洗）——去油污（按工艺规定）——冲洗（用冷水或热水冲洗）——酸洗（按工艺规定）——冲洗（用冷水或热水冲洗）——消除残存氧化物和焊接飞溅物。

检验——钝化（按工艺规定）——冲洗（用冷水或热水冲洗）中和——检验。

3.表面处理（酸洗、钝化）工艺规程：3.1去油污用砂布或回丝蘸汽油或四氯化碳镲拭酸洗零部件的全部表面，一般须檫二遍，对油污较多处檫干净为止。

3.2酸洗：酸洗液配制如下（膏剂酸洗）硝酸（HNO3）20%盐酸（HCL）10%水（H20）70%糊精粉10%（液体重量比）滑石粉调至浆糊状酸洗时间40—60分钟酸洗温度室温酸洗方法膏剂法说明：先按配方配好酸液，再用滑石粉调成浆糊状膏剂，然后将膏剂均匀涂在不锈钢件表面，达到规定时间后将膏剂去掉，然后进行水洗。

注意：凡有碳素钢件表面应涂防腐蚀漆保护。

3.3钝化：钝化液配制如下：硝酸（HNO3）60%水（H20）40%糊精粉10%（液体重量比）滑石粉调至浆糊状钝化温度室温钝化时间2-3小时钝化方法膏剂法说明：先按配方比例配好钝化液，再用滑石粉调成浆糊状膏剂，然后将膏剂均匀涂在不锈钢件表面，达到规定时间后将膏剂去掉，然后进行水洗。

注意：1.碳素钢表面应涂防腐蚀漆保护。

Designation:A967–01e1Standard Specification forChemical Passivation Treatments for Stainless Steel Parts1 This standard is issued under thefixed designation A967;the number immediately following the designation indicates the year of original adoption or,in the case of revision,the year of last revision.A number in parentheses indicates the year of last reapproval.A superscript epsilon(e)indicates an editorial change since the last revision or reapproval.e1N OTE—Paragraph3.1.1.5was deleted editorially in April2002.Paragraph10.2was corrected editorially in April2002.1.Scope1.1This specification covers several different types of chemical passivation treatments for stainless steel parts.It includes recommendations and precautions for descaling, cleaning,and passivation of stainless steel parts.It includes several alternative tests,with acceptance criteria,for confirma-tion of effectiveness of such treatments for stainless steel parts.1.2Practices for the mechanical and chemical treatments of stainless steel surfaces are discussed more thoroughly in Practice A380.1.3Several alternative chemical treatments are defined for passivation of stainless steel parts.Appendix X1gives some nonmandatory information and provides some general guide-lines regarding the selection of passivation treatment appropri-ate to particular grades of stainless steel but makes no recommendations regarding the suitability of any grade,treat-ment,and acceptance criteria for any particular application or class of applications.1.4The tests in this specification are intended to confirm the effectiveness of passivation,particularly with regard to the removal of free iron and other exogenous matter.These tests include the following practices:1.4.1Practice A—Water Immersion Test,1.4.2Practice B—High Humidity Test,1.4.3Practice C—Salt Spray Test,1.4.4Practice D—Copper Sulfate Test,1.4.5Practice E—Potassium Ferricyanide–Nitric Acid Test, and1.4.6Practice F—Free Iron Test.1.5The values stated in inch-pound units are to be regarded as the standard.The SI units given in parentheses are for information only.1.6The following precautionary caveat pertains only to the test method portions,Sections14through18of this specifica-tion:This standard does not purport to address all of the safety concerns,if any,associated with its use.It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.2.Referenced Documents2.1ASTM Standards:A380Practice for Cleaning,Descaling,and Depassivation of Stainless Steel Parts,Equipment,and Systems2B117Practice for Operating Salt Spray(Fog)Apparatus3 B254Practice for Preparation of and Electroplating on Stainless Steel42.2Federal Specification:QQ-P-35C Passivation Treatments for Corrosion-Resistant Steels53.Terminology3.1Definition of Term Specific to This Standard—It is necessary to define which of the several commonly used definitions of the term passivation will be used in this specification.(See Discussion.)3.1.1Discussion—Stainless steels are autopassivating in the sense that the protective passivefilm is formed spontaneously on exposure to air or moisture.The presence of exogenous surface contamination,including dirt,grease,free iron from contact with steel tooling,and so forth,may interfere with the formation of the passivefilm.The cleaning of these contami-nants from the stainless steel surface will facilitate the spon-taneous passivation by allowing the oxygen uniform access to the surface.The passivefilm may be augmented by chemical treatments that provide an oxidizing environment for the stainless steel surface.3.1.1.1In this specification,passivation,unless otherwise specified,is defined as the chemical treatment of a stainless steel with a mild oxidant,such as a nitric acid solution,for the purpose of the removal of free iron or other foreign matter,but which is generally not effective in removal of heat tint or oxide scale on stainless steel.In the case of stainless steels with additions of sulfur for the purpose of improved machinability,1This specification is under the jurisdiction of ASTM Committee A01on Steel, Stainless Steel,and Related Alloys and is the direct responsibility of Subcommittee A01.14on Methods of Corrosion Testing.Current edition approved Oct.10,2001.Published December2001.Originally published as A967–st previoius edition A967–99.2Annual Book of ASTM Standards,V ol01.03.3Annual Book of ASTM Standards,V ol03.02.4Annual Book of ASTM Standards,V ol02.05.5Available from Superintendent of Documents,ernment Printing Office,Washington,DC20402.1Copyright©ASTM International,100Barr Harbor Drive,PO Box C700,West Conshohocken,PA19428-2959,UnitedStates.passivation may also include the removal of sulfides from the surface of the metal for the purpose of maximizing corrosion resistance.3.1.1.2The formation of the protective passivefilm on a stainless steel,also called passivation in a more general context,will occur spontaneously in air or other oxygen-containing environment when the stainless steel surface is free of oxide scale and exogenous matter.3.1.1.3Chemical treatments,such as sodium dichromate solutions,may facilitate the more rapid formation of the passivefilm on a stainless steel surface already free of scale or foreign matter.Such treatments,also sometimes called passi-vation in common usage,are designated as post-cleaning treatments in this specification in order to distinguish them from chemical treatments capable of removing free iron from stainless steels.3.1.1.4The chemical treatments capable of removing heat tint or oxide scale from stainless steel and capable of dissolving the stainless steel itself,typically called pickling,are substan-tially more aggressive than treatments used for passivation,as defined in3.1.1.1.The surface of stainless steel that has been pickled is free of scale,free iron,and exogenous foreign matter,and does not require a separate treatment for passiva-tion as defined in3.1.1.1.The passivation process defined in 3.1.1.2will occur without further chemical treatment but may be augmented and improved by the post-cleaning treatments defined in3.1.1.3.3.1.1.5Electrochemical treatments,including electropick-ling and electropolishing capable of removing heat tint or oxide scale from stainless steel and capable of dissolving the stainless steel itself,are substantially more aggressive than treatments used for passivation,as defined in3.1.1.1.The surface of stainless steel resulting from these treatments is free of scale, free iron,and exogenous foreign matter,and does not require a separate treatment for passivation as defined in3.1.1.1.The passivation process defined in 3.1.1.2will occur without further chemical treatment,but may be augmented and im-proved by the post-cleaning treatments defined in 3.1.1.3. Statements regarding chemical treatments,unless otherwise specified,are taken to include electrochemical treatments.4.Ordering Information4.1It is the responsibility of the purchaser to specify a test practice appropriate to any particular material and application. This specification was written for the purpose of providing an alternative to United States Federal Specification QQ-P-35C. Determination of the suitability of this specification for that purpose is the responsibility of the purchaser.4.2Unless specified by the purchaser,the chemical treat-ment applied to the stainless steel parts shall be selected by the seller from among the listed passivation treatments.5.Materials and Preparation for Passivation Treatments 5.1The passivation treatments shall be of one or more of the following types.The effectiveness of a particular treatment for a particular grade of stainless steel in a particular application is demonstrated by meeting the specified testing requirements: 5.1.1Treatments in nitric acid,5.1.2Treatments in citric acid,5.1.3Other chemical treatments,including electrochemical treatments,5.1.4Neutralization,and5.1.5Post-cleaning treatments.5.2Materials:5.2.1The chemicals used for passivation treatments shall produce passivated surfaces that meet the requirements of one or more of the tests of this specification.Attention shall be given to maintaining adequate volume,concentration,purity, and temperature control appropriate to the size and amount of stainless steel to be treated.5.2.2The processor shall maintain a record with regard to concentration and temperature of the passivation solution sufficient to demonstrate that the specified passivation condi-tions were maintained for each lot of stainless steel parts processed.Such records shall be available for inspection when specified in the purchase order.The processor is not required to reveal the precise composition of proprietary chemical mix-tures but shall maintain a unique identification of the mixture that will ensure its accurate representation for subsequent use.5.2.3The processor shall be responsible for the safe dis-posal of all material generated by this process.5.3Preparation for Passivation Treatments:5.3.1The pretreatment methods and procedures used prior to the passivation treatment,including mechanical and chemi-cal methods,singly or in combination,for descaling and pickling,shall be in accordance with Practice A380.When electrochemical cleaning is required,it shall be performed in accordance with Practice B254.5.3.2The resulting pretreated surface shall be substantially free of oil,grease,rust,scale,and other foreign matter.5.3.3When thefinal pretreatment of a part includes pickling of the entire surface of the part,no further passivation treatment is required prior to testing of the surface unless specified by the purchaser.6.Treatments in Nitric Acid Solutions6.1Passivation Treatment:6.1.1Stainless steel parts shall be treated in one of the following aqueous solutions and maintained within the speci-fied temperature range for the specified time.6.1.1.1Nitric1—The solution shall contain20to25volume percent of nitric acid and2.5+0.5weight percent of sodium dichromate.The parts shall be immersed for a minimum of20 min at a temperature in the range from120to130°F(49to 54°C).6.1.1.2Nitric2—The solution shall contain20to45volume percent of nitric acid.The parts shall be immersed for a minimum of30min at a temperature in the range from70to 90°F(21to32°C).6.1.1.3Nitric3—The solution shall contain20to25volume percent nitric acid.The parts shall be immersed for a minimum of20min at a temperature in the range from120to140°F(49 to60°C).6.1.1.4Nitric4—The solution shall contain45to55volume percent of nitric acid.The parts shall be immersed for a minimum of30min at a temperature in the range from120to 130°F(49to54°C).6.1.1.5Nitric5—Other combinations of temperature,time, and concentration of nitric acid,with or without other chemi-cals,including accelerants,inhibitors,or proprietary solutions, capable of producing parts that pass the specified test require-ments.6.2Water Rinse—Immediately after removal from the pas-sivating solution the parts shall be thoroughly rinsed,using stagnant,countercurrent,or spray washes singly or in combi-nation,with or without a separate chemical treatment for neutralization(see9.1)of the passivation media,with afinal rinse being carried out using water with a maximum total solids content of200ppm.7.Treatments in Citric Acid7.1Passivation Treatment:7.1.1Stainless steel parts shall be treated in one of the following aqueous solutions and maintained within the speci-fied temperature range for the specified time.7.1.1.1Citric1—The solution shall contain4to10weight percent of citric acid.The parts shall be immersed for a minimum of4min at a temperature in the range from140to 160°F(60to71°C).7.1.1.2Citric2—The solution shall contain4to10weight percent of citric acid.The parts shall be immersed for a minimum of10min at a temperature in the range from120to 140°F(49to60°C).7.1.1.3Citric3—The solution shall contain4to10weight percent of citric acid.The parts shall be immersed for a minimum of20min at a temperature in the range from70to 120°F(21to49°C).7.1.1.4Citric4—Other combinations of temperature,time, and concentration of citric acid,with or without other chemi-cals to enhance cleaning,including accelerants,inhibitors,or proprietary solutions capable of producing parts that pass the specified test requirements.7.1.1.5Citric5—Other combinations of temperature,time, and concentrations of citric acid,with or without other chemi-cals to enhance cleaning,including accelerants,inhibitors,or proprietary solutions capable of producing parts that pass the specified test requirements.Immersion bath to be controlled ata pH of1.8–2.2.7.2Water Rinse—Immediately after removal from the pas-sivating solution,the parts shall be thoroughly rinsed,using stagnant,countercurrent,or spray washes,singly or in combi-nation,with or without a separate chemical treatment for neutralization of the passivation media(see9.2),with afinal rinse being carried out using water with a maximum total solids content of200ppm.8.Treatments in Other Chemical Solutions,IncludingElectrochemical Treatments8.1It is recognized that the purpose of removal of all exogenous matter from a stainless steel surface,including the removal of free iron,can be accomplished by different media, with potential for benefits to be gained from use of proprietary skills and art,including proprietary passivation media.Such treatments may include externally applying an electrical po-tential on the stainless steel parts,as in the case of electropol-ishing.The suitability of such passivation treatments for use in meeting the requirements of this specification shall be deter-mined by the capability of the processed parts meeting the specified test requirements.8.2Stainless steel parts shall be treated in a specified aqueous solution,with or without externally applied electrical potential,and maintained within a specified temperature range for a time sufficient for the processed parts to meet the specified test requirement.8.3Water Rinse—Immediately after removal from the pas-sivating solution,the parts shall be thoroughly rinsed,using stagnant,countercurrent,or spray washes,singly or in combi-nation,with or without a separate chemical treatment for neutralization of the passivation media(see9.2),with afinal rinse being carried out using water with a maximum total solids content of200ppm.9.Neutralization9.1The chemical reactions of the passivating media on the surface of the stainless steel shall be stopped by rinsing of the stainless steel part,with or without a separate neutralization treatment.9.2The suitability of a neutralization procedure is deter-mined by the capability of the processed parts meeting the specified test requirements.(See Note1.)N OTE1—The selection of medium and procedures for a neutralization depends of the chemistry of the passivation and on economic consider-ations.An example of a neutralizing treatment would be immersion of the part for a minimum of30min in a solution of5%NaOH at160to180°F (71to82°C),followed by a water rinse.10.Post-Cleaning Treatments10.1Although the passivefilm characteristic of stainless steel will form spontaneously in air or any other oxygen-containing environment,the processor shall,when specified, apply a chemical treatment that will accelerate the formation of the passivefilm on a chemically clean stainless steel surface. An example of a medium that serves to accelerate the forma-tion of the passivefilm but does not contribute to the removal of free iron from the stainless steel surface would be an aqueous solution of sodium dichromate.10.2When specified,within one hour after thefinal water rinse as required in6.2,7.2,or8.3,all ferritic and martensitic steel parts shall be immersed in an aqueous solution containing 4to6weight percent of sodium dichromate at a temperature in the range from140to160°F(60to71°C)for a minimum of30 min,followed by a rinse in accordance with6.2,7.2,or8.3. The parts shall then be thoroughly dried.10.3The purchaser may specify other post-cleaning treat-ments.11.Finish11.1The passivated parts shall exhibit a chemically clean surface and shall,on visual inspection,show no etching, pitting,or frosting resulting from the passivation procedures.12.Testing Agency12.1When required,the purchaser shall be permitted to perform such inspections as necessary to determine that the testing agency is capable of performing the specifiedtest.13.Lot,Frequency of Testing,and Selection of Test13.1Definition of Lot—A lot shall consist of one of the following,at the option of the processor:13.1.1The passivated parts of similar alloy and manufac-turing methods that are pretreated and passivated in a single day or within a time frame that will ensure consistent passiva-tion results;13.1.2The passivated parts of the same product of one size from one heat in one shipment;or13.1.3When few parts are involved,the passivated parts from an entire production run.13.2Unless a greater frequency of testing is specified on the purchase order,one test per lot shall be sufficient.13.3One or more of the following tests,when specified on the purchase order,shall be performed on each lot of stainless steel parts.Not all of the following tests are suitable for all grades of stainless steel.(See Note2.)13.3.1Practice A—Water Immersion Test,13.3.2Practice B—High Humidity Test,13.3.3Practice C—Salt Spray Test,13.3.4Practice D—Copper Sulfate Test,and13.3.5Practice E—Potassium Ferricyanide–Nitric Acid Test.N OTE2—Some of the tests may produce positive indications not associated with the presence of free iron on the stainless steel surface.An example would be application of Practice C on some lesser-alloyed martensitic or ferritic stainless steels.14.Practice A—Water Immersion Test14.1This test is used for the detection of free iron or any other anodic surface contaminants on stainless steel.14.2The sample representing the lot of passivated parts shall be alternately immersed in a non-rusting tank of distilled water for1h and allowed to dry in air for1h.This cycle shall be repeated a minimum of twelve times.14.3The tested sample shall not exhibit rust or staining attributable to the presence of free iron particles embedded in the surface.15.Practice B—High Humidity Test15.1This test is used for the detection of free iron or any other anodic surface contaminants on stainless steel.15.2The test shall be performed using a humidity cabinet capable of maintaining the specified test conditions.15.3The sample representing the lot of passivated parts shall be cleaned by immersion in acetone or methyl alcohol or by swabbing with a clean gauze saturated with acetone or methyl alcohol,and dried in an inert atmosphere or desiccated container.The cleaned and dried part shall be subjected to97 63%humidity at10065°F(3863°C)for a minimum of 24h.15.4The tested sample shall not exhibit rust or staining attributable to the presence of free iron particles imbedded in the surface.16.Practice C—Salt Spray Test16.1This test is used for the detection of free iron or any other anodic surface contaminants on stainless steel.16.2The sample representing the lot of passivated parts shall be tested by the salt spray test conducted in accordance with Practice B117for a minimum of2h using a5%salt solution.16.3The tested sample shall not exhibit rust or staining attributable to the presence of free iron particles imbedded in the surface.17.Practice D—Copper Sulfate Test17.1This test is recommended for the detection of free iron on the surface of austenitic stainless steels in the200and300 series,precipitation hardened stainless steels,and ferritic400 series stainless steels having a minimum of16%chromium. This test is not recommended for martensitic400series stainless steels or for ferritic400series stainless steels with less than16%chromium because these steels will give a positive indication irrespective of the presence or absence of anodic surface contaminants.This test shall not be applied to parts to be used in food processing.17.2The test solution is prepared by dissolving4g of copper sulfate pentahydrate(CuSO4·5H2O)in250mL of distilled water to which1mL of sulfuric acid(H2SO4,sp gr 1.84)has been added.Aqueous copper sulfate solutions more than two weeks old shall not be used for this test.17.3The test solution is swabbed on the surface of the sample representing the lot of passivated parts,applying additional solution as needed to keep the surface wet for a period of at least6min.At the end of this period,the surface shall be carefully rinsed and dried with care taken not to disturb copper deposits if present.17.4The tested sample shall not exhibit copper deposits.18.Practice E—Potassium Ferricyanide–Nitric Acid Test 18.1This test is recommended when detection of very small amounts of free iron is required.It is recommended for detection of free iron on austenitic200and300series stainless steels.This test is not recommended for detection of free iron on ferritic or martensitic400series stainless steels,because these steels will give a positive indication irrespective of the presence or absence of anodic surface contaminants.This test shall not be applied to parts to be used in food processing. 18.2The test solution is prepared by adding10g of chemically pure potassium ferricyanide to500mL of distilled water,adding30mL of70%nitric acid,agitating until all of the ferricyanide is dissolved,and diluting to1000mL with distilled water.The test solution shall be mixed fresh on the day of the test.18.3The test solution is swabbed on the surface of the sample representing the lot of passivated parts.The formation of a dark blue color within30s denotes the presence of metallic iron.18.4The tested sample shall not exhibit the dark blue color indicative of free iron on the surface.18.5When the test is negative,the surface shall be thor-oughly washed with warm water to removal all traces of the test solution.When the test is positive,the dark blue stain shall be removed with a solution of10%acetic acid and8%oxalic acid,followed by a thorough hot waterrinse.19.Practice F—Free Iron Test19.1This test is used for the detection of free iron on the surface of stainless steel.It is especially useful for large parts that have been uniformly cleaned but that are inconvenient for reasons of size of equipment or ease of handling of the part to place in the environments defined in Practice A(Section14)or Practice B(Section15).Unless otherwise specified by the purchaser,the number of tests and the locations of the tests shall be at the option of the processor to assure a representative testing of the part.19.2The test is performed by placing a clean cloth pad that has been thoroughly soaked with distilled or deminaralized water on the surface of the part at a part temperature of50°F (10°C)or greater for a period of not less than60minutes.The cloth shall be in contact with the steel for an area of at least20 square inches(130cm2).The pad shall be maintained wet through the test period,either by a method of retarding external evaporation,by the further addition of potable water,or by backing the pad with a sponge or similar water source.The cloth pad used shall be used for only one such test,being changed for each test so as to avoid risk of contamination. After removal of the cloth pad,the surface of the part shall be allowed to dry in air before inspection.19.3The tested part shall not exhibit rust or staining attributable to the presence of free iron particles embedded in the surface.20.Rejection and Retest20.1Any lot failing to meet the specified test requirements of the purchase order shall be rejected.A rejected lot may,at the option of the processor,be re-passivated,with or without re-pretreatment,and then be retested.The number of samples tested from a lot subject to retest shall be twice the original specified test frequency,to the limit of the number of pieces in the lot.All samples must pass the specified acceptance criterion for the specified test for the retested lot to be accepted. 21.Precision and Bias21.1No statement is made concerning either the precision or bias of Practices A,B,C,D,and E because the results state merely whether there is conformance to the criteria for success specified in the procedure.22.Certification22.1When specified in the purchase order,a report of the practice and tests used,including the record of process condi-tions when specified in accordance with 3.1.1.2,shall be supplied to the purchaser.APPENDIX(Nonmandatory Information)RMATION REGARDING PASSIV ATION TREATMENTSN OTE X1.1—The following information is based on a section of Federal Specification QQ-P-35C(Oct.28,1988)identified as information of a general or explanatory nature that may be helpful,but is not mandatory. Minor changes have been made in the text to facilitate references to the main document and to correct technical inaccuracies.X1.1Intended Use—The passivation treatments provided by this specification are intended to improve the corrosion resistance of parts made from stainless steels of all types.X1.1.1During processing operations such as forming,ma-chining,tumbling,and lapping,iron particles or other foreign particles may become smeared over or imbedded into the surface of stainless steel parts.These particles must be re-moved or they will appear as rust or stain spots.This condition may be prevented by chemically treating the parts to remove the iron particles or other foreign particles,and then allowing the passivefilm to form on the cleaned surface,with or without chemical enhancement of the formation of this oxidefilm.X1.1.2This specification is not intended for the black oxide coating of parts typically used for photographic or optical instruments.X1.2Ordering Data—Purchasers should select the pre-ferred options permitted by this specification and include the following information in the purchase order:X1.2.1Title,number,and date of this specification;X1.2.2Identification of material by type and applicable product specification;X1.2.3Test practices to be imposed(see1.4);X1.2.4Definition of lot size,if other than described in this specification;andX1.2.5Required documentation,if other than the minimum required by this specification.X1.3Grades of Stainless Steel—Different types of stainless steel are selected on a basis of properties required,for example, corrosion resistance and design criteria,and fabrication re-quirements.Table X1.1is a compilation that serves as a guide for the selection of passivation treatment for different grades, but is far from complete either in grades or in passivation treatments.X1.4Clean Water—Clean water is defined as water con-taining a maximum total solid content of200ppm.Rinsing can be accomplished by a combination of stagnant,countercurrent or spray rinses,or both,prior tofinal rinse.X1.5Chemically Clean Surface—A chemically clean sur-face is defined as a surface upon which water,when applied momentarily to the surface,will remain on that surface in an even,continuousfilm,and in addition is free of any foreign material or residualfilm deposit which would be detrimental to the quality of thepart.X1.6Test Specimens —When using test specimens instead of parts,the specimens can effectively represent the parts only if they have been exposed to the same processing steps,such as machining,grinding,heat treating,welding,and so forth,as the parts they are to represent.X1.7Carburized Surfaces —Stainless steel parts with car-burized surfaces cannot be passivated because the carbon combines with the chromium forming chromium carbides on the surface.X1.8Nitrided Surfaces —Stainless steel parts with nitrided surfaces should not be passivated because the treatment will severely corrode the nitrided case.X1.9This specification provides for the same passivation treatments as Fed.Spec.QQ-P-35C,but also includes a number of alternative passivation treatments.The effectiveness of any passivation treatment is demonstrated by the parts meeting the specified testing requirements after treatment.X1.10Martensitic Grade 440C —High-strength grades such as 440C are subject to hydrogen embrittlement or intergranular attack when exposed to acids.Cleaning by mechanical methods or other chemical methods is recom-mended.X1.11The salt spray test is typically used to evaluate austenitic stainless steels and may not be applicable to all martensitic or ferritic stainless steels.ASTM International takes no position respecting the validity of any patent rights asserted in connection with any item mentioned in this ers of this standard are expressly advised that determination of the validity of any such patent rights,and the risk of infringement of such rights,are entirely their own responsibility.This standard is subject to revision at any time by the responsible technical committee and must be reviewed every five years and if not revised,either reapproved or withdrawn.Your comments are invited either for revision of this standard or for additional standards and should be addressed to ASTM International Headquarters.Your comments will receive careful consideration at a meeting of the responsible technical committee,which you may attend.If you feel that your comments have not received a fair hearing you should make your views known to the ASTM Committee on Standards,at the address shownbelow.FIG.X1.1Recommended Nitric Acid Passivation Treatments for Different Grades of StainlessSteel。

不锈钢钝化操作规程不锈钢钝化操作规程第一章总则第一条为了保证不锈钢表面的美观性和耐腐蚀性能，规范不锈钢钝化操作，制定本规程。

第二条不锈钢钝化操作应遵循安全、环保、规范、高效的原则。

第三条本规程适用于工业生产过程中的不锈钢钝化操作。

第二章术语和定义第四条不锈钢：指含铬量不低于10.5%的铁基合金。

第五条钝化：指通过化学处理，表面形成一层致密、均匀、抗腐蚀的氧化膜，提高不锈钢耐腐蚀性能。

第六条钝化剂：指用于不锈钢钝化过程中的化学药剂。

第七条原液：指未经稀释的钝化剂。

第三章设备和材料第八条钝化槽：应采用耐腐蚀材料制作，有良好的密封性能，防止钝化剂泄漏。

第九条前处理设备：应配备清洗槽、酸洗槽等设备，确保表面无污物。

第十条不锈钢钝化剂：应选择符合国家标准的产品，严禁使用过期的钝化剂。

第四章操作流程第十一条准备工作：将待钝化的不锈钢表面清洗干净，去除油污和锈蚀物。

第十二条配制钝化液：按照钝化剂的使用说明书，根据不锈钢的种类和数量，正确配比钝化液。

第十三条钝化槽处理：将准备好的钝化液倒入钝化槽中，使其表面充分浸泡。

第十四条设定时间：根据不锈钢的种类和厚度，设定合适的钝化时间。

第十五条钝化处理：将待钝化的不锈钢表面浸泡在钝化槽中，保证不锈钢表面完全与钝化液接触。

第十六条清洗处理：钝化处理完成后，将不锈钢表面用清水进行充分冲洗，去除残留的钝化液。

第十七条检验合格：经过钝化处理的不锈钢表面应均匀、致密，无色差、斑点和脱层等现象，并且经化学验收合格。

第五章安全和环保措施第十八条操作人员应穿戴好防护设备，如防护眼镜、手套、防护服等。

第十九条操作过程中应注意通风，避免钝化剂气味对人体造成危害。

第二十条不锈钢钝化液及废弃料应进行专门收集和储存，严禁直接排放到水体中。

第六章附则第二十一条针对特殊材质和工艺的不锈钢钝化操作，应编制相应的专项规程。

第二十二条违反本规程的操作行为，将依据相关安全和环保法律法规予以处理。

第二十三条本规程由不锈钢钝化操作管理人员执行，并在作业现场随时提供给操作人员。

不锈钢部件的化学钝化处理的标准技术规范(中英文对照1. Scope1.范围1.1 This specification covers several different types of chemical passivation treatments for stainless steel parts. It includes recommendations and precautions for descaling, cleaning, and passivation of stainless steel parts. It includes several alternative tests, with acceptance criteria, for confirmation of effectiveness of such treatments for stainless steel parts.1.1本技术规范适用于几种不同类型不锈钢部件的化学钝化处理。

本技术规范包括:不锈钢部件除垢、清洁、钝化的建议和防护;本技术规范包括了几种可供选择的有验收标准的不锈钢部件处理效果确认的检测。

1.2 Practices for the mechanical and chemical treatments of stainless steel surfaces are discussed more thoroughly in Practice A 380.1.2 不锈钢表面物理和化学处理的作业在作业A380里有更详尽的论述。

1.3 Several alternative chemical treatments are defined for passivation of stainless steel parts. Appendix X1 gives some nonmandatory information and provides some general guidelines regarding the selection of passivation treatment appropriate to particular grades of stainless steel. It makes no recommendations regarding the suitability of any grade, treatment, or acceptance criteria for any particular application or class of applications.1.3 几种可供选择的不锈钢部件化学钝化处理在此有详细规定。

304不锈钢是一种常见的不锈钢材料，常用于制造医疗设备、制药设备和食品加工设备等领域。

药水检测标准通常用于评估不锈钢材料在与药水接触时的耐腐蚀性和化学稳定性。

以下是一些可能适用于304不锈钢材质药水检测的标准和测试方法的一般指导：ASTM A380 - "Standard Practice for Cleaning, Descaling, and Passivation of Stainless Steel Parts,Equipment, and Systems"：这一标准涵盖了不锈钢材料的清洁、除垢和钝化处理。

钝化是一种通过化学方法来增强不锈钢材料对腐蚀的抵抗力的过程。

该标准可以用于确保不锈钢在与药水接触时不会受到腐蚀的影响。

ASTM A967 - "Standard Specification for Chemical Passivation Treatments for Stainless Steel Parts"：这个标准详细描述了化学钝化不锈钢材料的要求和测试方法。

它确保了钝化过程的质量，从而提高了不锈钢的耐腐蚀性。

ASTM A262 - "Standard Practices for Detecting Susceptibility to Intergranular Attack in AusteniticStainless Steels"：这个标准用于检测奥氏体不锈钢（包括304不锈钢）的晶间腐蚀敏感性。

如果不锈钢材料在与药水接触时有晶间腐蚀的风险，可以使用这个标准来评估其耐腐蚀性。

使用pH值和化学成分监测：根据药水的特性，可以使用pH值计或化学成分分析来监测不锈钢材料与药水之间的相互作用。

这可以帮助确定是否需要额外的保护措施或测试。

请注意，具体的检测标准和测试方法可能会根据不同的应用、药水的成分以及设备的设计和使用条件而有所不同。

不锈钢硝酸与柠檬酸钝化的工艺不锈钢是一种固有的抗腐蚀材料，但是当对不锈钢进行机械加工，成型或加工时，可以将游离铁引入到基材表面上。

用诸如硝酸或柠檬酸之类的氧化性酸对不锈钢进行适当的钝化处理会除去这种游离铁，并促进薄而致密的保护性氧化层的生长，从而使不锈钢的耐腐蚀性最大化。

对于不锈钢的类型和最终应用，某些钝化工艺可能会比其他钝化工艺表现更好。

就让我们杰昌电镀来说说吧，我们将比较硝酸和柠檬酸的钝化作用，这是ASTM A967和AMS 2700中指定的两种主要化学方法。

硝酸钝化硝酸钝化在比较硝酸钝化与柠檬酸钝化时，整个行业中最常用的方法是硝酸钝化。

硝酸钝化工艺是QQ-P-35中规定的原始钝化工艺，这是第一个涉及钝化的军事规范。

硝酸钝化提供了多种选项，可自定义酸的氧化电位，以适合特定等级的不锈钢。

硝酸钝化的各种方法和类型包括几种加热选项以及包括重铬酸钠的选项。

硝酸浓度越高，硝酸温度越高，钝化化学物质的氧化电位越高。

也可以将重铬酸钠添加到硝酸中，以提高镀液的氧化能力，使其更适合用于耐蚀性较低的不锈钢，例如沉淀硬化，马氏体和铁素体等级的不锈钢。

这些等级的不锈钢中的镍和铬含量较低，这使其更易于被腐蚀。

化学物质的氧化电位越高，在表面上形成钝化氧化物阻挡层的速度越快，效果越好，从而降低了腐蚀电位。

以下是根据ASTM A967进行的各种硝酸钝化方法的浓度和时间：钝化化学物的污染会导致表面的点蚀，从而产生严重腐蚀或变暗的表面。

导致点蚀的常见物质是氯化物，其来源多种多样，包括拖入酸中或在水中使用氯化物。

此外，钝化槽中的有机物堆积，例如未正确清洁的零件所产生的机加工油的引入，都可能导致不锈钢腐蚀。

因此，需要定期进行分析并维护钝化化学物质。

某些钝化方法也比其他方法更能抵抗点蚀。

用于硝酸钝化氧化电位增加的镀液也更能抵抗点蚀。

与柠檬酸相比，硝酸还具有更强的抗点腐蚀性。

柠檬酸钝化柠檬酸钝化是由Adolf Coors酿酒公司开发的，用于啤酒桶内部的钝化。

不锈钢设备及管道焊接钝化处理规程
目的：为了提高不锈钢的耐腐蚀性，防止材料晶间腐蚀
范围：所有不锈钢焊接部位
责任者：动力车间主任电焊人员设备主管
程序：
1 酸洗钝化工艺过程如下:
酸洗→冲洗→钝化
前处理→→冲洗干净
酸洗钝化(二合一)膏(涂刷)
1.1前处理
，必要时可采用2.5%Na3PO4碱洗液碱洗,碱洗后需用清水将表面冲洗干净。

1.2酸洗及冲洗
用硝酸（HNO3）、盐酸（HCL）和水按2︰1︰7的比例配制成溶液，再与糊精粉按1︰9的比例混合，加滑石粉调至浆糊状。

在室温下将膏剂均匀的涂在需要酸洗的部位，经40－60分钟后，将膏剂去掉，然后用水冲洗干净，使之表面不留存残液。

（对被酸洗产品上的碳钢件能拆卸的需拆卸掉，如不能拆卸的需涂防护油漆或封橡胶泥）
1.3钝化及冲洗
用硝酸（HNO3）和盐酸（HCL）按6︰4的比例配制成溶液，再与糊精粉按1︰9的比例混合，加滑石粉调至浆糊状。

在室温下将膏剂均匀的涂在已酸洗部位，经2－3小时后，将膏剂去掉，然后用水冲洗干净，使之表面不留残液。

1.4 酸洗钝化(二合一)膏(涂刷)及冲洗
,氧化皮较厚处可略涂厚些。

,根据原材料的厚度使钝化膏保持5－30分钟。

,直至表面呈显均匀的银白色。

2 酸洗钝化的质量检验
2.1 外观检验
酸洗钝化表面应呈现均匀的银白色，不得有明显的腐蚀痕迹,焊缝及热影响区表面不得有氧化色,不得有颜色不均匀的斑痕。

2.2 残液检验
用酚酞试纸检查表面上残液的冲净程度pH值中性为合格。

不锈钢酸洗钝化工艺规程-标准化文件发布号：（9456-EUATWK-MWUB-WUNN-INNUL-DDQTY-KII目录1内容与适用范围 (3)1.1主题内容 (3)1.2适用范围 (3)2引用文件 (3)3酸洗、钝化工艺 (3)3.1酸洗、钝化前的预处理 (3)3.1.1 酸洗材料 (3)3.1.2 钝化处理的准备 (3)3.2酸洗钝化操作 (4)3.2.1 酸洗 (4)3.2.2钝化 (4)3.2.2清洗 (4)4检验 (4)4.1 外观检验 (4)4.2 残液检验 (5)4.3 钝化膜致密性检验 (5)4.4 检验钝化表面碳钢微粒 (5)5记录 (5)1内容与适用范围1.1主题内容本规程规定了不锈钢容器（包括零部件）表面油污、锈渍的清理、酸洗及钝化的要求、方法和注意事项。

1.2适用范围本规程适用于镍奥氏体不锈钢容器的酸洗钝化处理。

2引用文件以下引用标准、文件应为最新版本。

当本规程与新标准、文件内容冲突时，冲突部分按最新标准、文件相应规定内容执行。

ASTM A967 不锈钢部件化学钝化处理标准ASTM A380 不锈钢零件、设备和系统的清洗和除垢RCC-M 法国核电厂设计和建造规则（第8册 F篇F6534）3酸洗、钝化工艺3.1酸洗、钝化前的预处理3.1.1 酸洗材料3.1.1.1用于钝化处理的化学物质必须能产生符合该标准中一种或多种要求的钝化表层。

根据测试用不锈钢的大小和数量，注意所选化学物质的计量、浓度、纯净度及化学反应的温度。

3.1.1.2操作员必须记录钝化溶液的浓度和温度以此证明处理每批不锈钢都需要特定的钝化环境。

操作者禁止泄漏专利化学混合物的精确成份，但是必须对混合物质做唯一的区别标记以便下次使用时精确无误。

3.1.1.3操作者负责安全处理化学处理过程中产生的所有物质。

3.1.2 钝化处理的准备3.1.2.1钝化处理前的预处理方法和过程，包括除锈和酸浸的机械和化学处理方法是否单独使用或者两者结合使用，必须符合实验ASTM A380的要求。

astm967标准内容
ASTM 967标准内容是涂层在金属和非金属基材上使用的清洗方法的指南。

该
标准的目的是确保涂层能够附着牢固且持久，并且能够提供所需的保护性能。

ASTM 967标准详细描述了几种不同的清洗方法，包括机械清洗、溶剂清洗和
表面活性剂清洗。

机械清洗方法使用机器或设备对基材表面进行清洗，以去除表面的污垢和杂质。

溶剂清洗方法则使用溶剂来溶解和清除表面的油脂、沉积物和其他污垢。

表面活性剂清洗方法通过使用表面活性剂来降低液体的表面张力，以便更好地清洗表面。

ASTM 967标准还规定了清洗剂的使用和评估，包括对清洗剂的配方、浓度、
温度和清洗时间的要求。

此外，该标准还提供了评估清洗效果的方法，包括对清洗后表面的外观、油迹和残留物的检查。

符合ASTM 967标准的清洗方法可以确保涂层在应用过程中的可靠性和耐久性。

通过正确清洗基材表面，涂层能够更好地附着，并能够提供所需的保护性能，如耐腐蚀性、耐磨性和耐候性。

总之，ASTM 967标准对于涂层应用中的清洗过程具有重要的指导作用。

遵循
该标准的要求，可以确保清洁的基材表面，从而提供高质量的涂层。

不锈钢钝化技术标准
1. 化学成分标准，不同类型的不锈钢材料需要遵循不同的化学成分标准，以确保钝化处理后的表面质量和耐腐蚀性能符合要求。

这包括钝化溶液中的化学成分和浓度等方面的标准。

2. 处理工艺标准，钝化处理的工艺包括预处理、钝化处理和后处理等环节，需要遵循一定的工艺标准，如处理温度、处理时间、搅拌速度、PH值等参数的控制要求。

3. 膜层性能标准，钝化处理后形成的膜层应具有一定的厚度、致密性、耐蚀性和装饰性能。

因此，钝化技术标准中通常包括对膜层性能的测试方法和要求。

4. 环保标准，钝化处理液及废水处理应符合环保要求，需要遵循相关的环保标准，确保不对环境造成污染。

5. 检测标准，对钝化处理后的不锈钢材料需要进行一系列的检测，如耐蚀性测试、膜层厚度测试等，这些检测需要符合相应的标准和方法。

总的来说，不锈钢钝化技术标准涵盖了材料、工艺、环保和质量检测等多个方面的要求，旨在确保钝化处理后的不锈钢材料具有良好的耐腐蚀性能和装饰性能，并且符合相关的法律法规和环保要求。

制定和遵循这些标准对于保障不锈钢制品的质量和安全具有重要意义。

酸洗钝化在制药行业中的应用摘要：随着国家对医药事业越来越重视，相关法律法规不断出台，我国的制药行业也在不断的发展。

制药行业尤其是无菌和生物制药生产企业会用到大量的不锈钢材质设备，都与药品直接接触。

这些不锈钢设备都需要进行防腐蚀处理，保证药品生产质量，所以要充分研究酸洗钝化技术的开发和应用，从而更好的在制药行业中进行应用。

关键词：医药事业；制药行业；酸洗钝化；红锈；生物膜现如今制药行业尤其是无菌和生物制药生产企业会用到大量的不锈钢材质设备，都与药品直接接触，包括传统的纯化水系统、注射用水系统、CIP系统、配料系统、制剂的溶液分装等等。

如此大量的不锈钢系统在日常的使用以及定期的维保方面，酸洗钝化【1】是非常重要的，如果说不锈钢表面缺失了钝化的效果和钝化膜，那么它就起不到GMP所要求的抗腐蚀性。

所有的管道、储罐、阀门、喷淋球等等基础的原材料在供应商的工厂已经做过酸洗钝化，但为什么不锈钢系统在现场安装施工完成后还需要进行额外的酸洗钝化？主要是因为在现场的机加工后破坏了原有的不锈钢钝化膜，比如现场的一些切割、焊接加工处理，不管是手工焊还是自动焊都会破坏原有的钝化效果。

由于此原因，只要是对于管道、阀门等现场进行切割、焊接加工处理的都需要进行酸洗钝化。

1.基本概念钝化是指使金属表面转化为难氧化的状态而延缓金属腐蚀速度的方法。

钝化深度和表面金属元素的优化分布（如铬铁比）将决定金属钝化后的抗腐蚀性和腐蚀速率。

就提高标准等级不锈钢的抗腐蚀性而言，钝化处理是最佳选择，也是必要程序。

钝化是洁净表面有氧气存在时的自发现象，可在不锈钢表面生成致密的钝化膜。

通过化学处理，不锈钢表面的钝化膜可实现一定程度增强。

钝化的一个先决条件是对表面的清洗程序，不锈钢表面的清洗程序应包含所有必要的表面污物的清除（油脂、颗粒等）以保证合金表面最佳的抗腐蚀性能、保护产品不被污染的性能和合金表面外观的达标【2】。

最终化学钝化处理的目的是确保合金表面无铁元素及其他污物存在以实现最佳抗腐蚀状态。

不锈钢酸洗钝化执行标准
本标准规定了不锈钢酸洗钝化的操作流程和执行要求。

1.酸洗液成分
2.酸洗液应采用质量分数为10%～15%的硝酸溶液，并加入适量的氢氟酸或
草酸，根据材料种类和油污程度可适当调整溶液浓度和加入量。

3.酸洗温度
4.酸洗温度应控制在50℃～70℃之间，以避免温度过高导致材料表面氧化或
腐蚀。

5.浸泡时间
6.浸泡时间应根据材料种类、油污程度和酸洗液成分而定，一般为10分钟～
30分钟。

对于较重油污的材料，可适当延长浸泡时间。

7.钝化液浓度
8.钝化液应采用质量分数为2%～5%的硝酸溶液，根据材料种类和钝化要求
可适当调整溶液浓度。

9.钝化温度
10.钝化温度应控制在50℃～70℃之间，以避免温度过高导致材料表面氧化或
腐蚀。

11.钝化浸泡时间
12.钝化浸泡时间应根据材料种类、钝化要求和钝化液成分而定，一般为10分
钟～30分钟。

对于要求较高的材料，可适当延长浸泡时间。

13.预处理要求
14.在酸洗钝化之前，应对不锈钢表面进行清理，去除表面的油污、杂质、氧
化皮等，并用水冲洗干净。

对于一些特殊材料，如不锈钢合金或含有较高合金元素的不锈钢，应先进行试验，以确定最佳的酸洗钝化工艺参数。

15.后处理要求
16.酸洗钝化完成后，应对不锈钢表面进行清洗，去除残留的酸洗钝化液，并
用水冲洗干净。

对于一些要求较高的材料，可进行涂装或封闭处理，以增强防腐蚀性能。

A 水浸测试：这个测试在不锈钢中用于检测游离铁或任何其他阳极表面污染物。

同一钝化批次的样本应轮流浸在不锈槽的蒸馏水中1 h和在空气中干燥1 h。

这个周期应被重复至少12次。

被测样品不能因为游离铁的存在而生锈或着色。

B 高湿度测试：这个测试在不锈钢中用于检测游离铁或任何其他阳极表面污染物。

试验应用一个湿度箱能够维护指定的测试条件。

被测钝化样品应浸在丙酮或甲醇中清洁或用带有丙酮或甲醇的渗透纱布擦拭，在惰性气体或干燥容器中干燥。

清洁干燥的部分应在温度38±3°C 湿度97±3 %环境中24H。

被测样品不能因为游离铁的存在而生锈或着色。

C 喷盐测试：这个测试在不锈钢中用于检测游离铁或任何其他阳极表面污染物。

被测钝化样品的喷盐测试按Practice B117 用5 %盐液浸泡至少2H。

被测样品不能因为游离铁的存在而生锈或着色。

D 硫酸铜测试：本测试建议用于200和300系列奥氏体钢等铬含量大于16%的表面游离铁测试。

本测试不能用于用在食品程序的样品。

试验方案用到4克CuSO4·5H2O在250毫升蒸馏水加1毫升硫酸（比重1.84）（注：先加水，后加酸！），擦拭在样品表面，至少保持样品潮湿6分钟，试样应以不去除任何沉积铜的方式冲洗和干燥。

铜的沉积指示游离铁的存在。

E 铁氰化钾硝酸盐测试：（国内俗称：蓝点测试）本测试建议用于200和300奥氏体钢需要检测极少量游离铁。

不能用于用在食品程序的样品。

需要准备加10克化学纯铁氰化钾于500毫升蒸馏水中，加30毫升70%硝酸溶液，搅拌至溶解并用蒸馏水稀释到1000毫升。

本试剂应在试验当天勾兑。

试剂在样品上擦拭，30秒内形成深蓝色表明游离铁的存在。

测试后样品表面不能有象征游离铁的深蓝色存在。

若测试没有变色，应彻底用温水冲洗去除所有溶剂痕迹；若测试变色，深蓝色的污垢应用10%的醋酸和8%的草酸，然后用开水彻底清洗F 游离铁测试：本测试对大部分均匀清洗样品有效但不便用于测试A和B的环境。

不锈钢酸洗与钝化规范——奥氏体不锈钢压力容器的酸洗钝化晨怡热管1 前言在我公司生产中，经常有不锈钢设备的制作，不锈钢设备由于接触到腐蚀性介质，会造成设备表面有明显的腐蚀痕迹及颜色不均匀的斑痕，因此对不锈钢设备表面的处理尤为关键，不锈钢设备表面的钝化处理就是一个重要环节。

设备表面钝化膜形成不完善，与铁离子接触造成污染，在使用过程中就会出现锈蚀现象，造成运行介质指标变化等。

下面就奥氏体不锈钢设备表面的酸洗钝化处理原理及实际操作的常规工艺过程谈一些看法，以供有关人员参考。

2 概述奥氏体不锈钢具有良好的耐腐蚀性能，而且还有良好的冷热加工性能，因此被广泛地用于制造各类具有防腐蚀要求的压力容器，奥氏体不锈钢表面的钝化膜，对其耐腐蚀有很大影响。

奥氏体不锈钢的钝化膜主要是通过对其表面进行酸洗钝化处理得来的。

3 酸洗钝化的原理3.1钝化：金属经氧化性介质处理后，其腐蚀速度比原来未处理前有显著下降的现象称金属的钝化。

其钝化机理主要可用薄膜理论来解释，即认为钝化是由于金属与氧化性介质作用，作用时在金属表面生成一种非常薄的、致密的、覆盖性能良好的、能中固地附在金属表面上的钝化膜。

这层膜成独立相存在，通常是氧和金属的化合物。

它起着把金属与腐蚀介质完全隔开的作用，防止金属与腐蚀介质直接接触，从而使金属基本停止溶解。

奥氏体不锈钢经氧化性介质处理后其表面能形成满足上述要求的钝化膜，但该钝化膜在起活化作用的Cl-、Br-、F-等卤素离子作用下，极易受到破坏。

这也就是虽经酸洗钝化处理的奥氏体不锈钢压力容器在进行水压试验后若不能将水渍除干净，但应控制水的Cl-含量不超过25ppm的原因之一。

另外并非任何金属的氧化膜都可视作钝化膜，如碳钢在高温氧化后形成的氧化膜由于不能满足牢固地附在金属表面的要求而不能充作钝化膜。

对于奥氏体不锈钢一般采用氧化性强的以硝酸为主剂的溶液来进行处理，为确保钝化处理的效果，在钝化前先对被钝化表面进行酸洗处理。

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更多免费资料下载： 德信诚培训网 不锈钢钝化技术操作规程
（ISO9001-2015/ISO45001-2018）
1.0目的
规范不锈钢通常要求的钝化作业指导。

2.0适用范围
适用于所有轨道项目的不锈钢产品的钝化操作
特殊要求的钝化效果需专门的钝化工艺
3.0职责
所有钝化的操作人员需严格按此工艺执行。

4.0定义
无。

5.0程序
5.1操作前准备
5.1.1确定钝化区域
5.1.2工具：钝化膏、毛笔、毛刷、高压水枪、抹布、压缩空气
5.2操作步骤
5.2.1使用压缩空气、酒精清洁待钝化区域的灰尘与油污；
5.2.2使用毛笔或毛刷涂钝化膏，涂抹的区域尽可能小；
5.2.3钝化膏涂抹的厚度为2~3mm ，不允许钝化膏有下淌的现象,，当发生钝化膏下淌现象立即使用抹布擦净；
5.2.4每类零件的涂抹工作须由专人负责，不允许多人同时操作；。

不锈钢部件化学钝化处理的标准规范1.范围1.1该规范包含了不同种类的不锈钢不见化学钝化处理的方法。

它包含对不锈钢不见进行除锈，清洗及钝化处理的优点和注意事项。

它列明了一些可替换用的测试方法保证对不锈钢部件的此类处理的有效性，并且这些方法都是符合相关标准的。

1.2实践A380中全面讨论了对不锈钢部件表面进行机械处理和化学处理的实验。

1.3为不锈钢部件钝化定义了一些可供选择的化学处理方法。

附录X1给出了一些非强制性信息，提供了对于不同级别的不锈钢如何正确选择钝化处理方法的一般指导，但是没有提出对特殊适应性或适应分类的级别，处理及规则的正确性提出参考建议。

1.4该规范提及的测试方法是为了证明钝化的有效性，特别是对于处理多余的铁和其他氧化物质时的有效性。

这些测试方法包括：1.4.1实验A-水浸测试1.4.2实验B-高湿度测试1.4.3实验C-喷盐测试1.4.4实验D-硫酸铜测试1.4.5实验E-铁氰化钾硝酸盐测试1.4.6实验F-铁离子测试1.5测试值的标准单位为英寸/磅。

括弧里的SI单位仅提供参考。

1.6以下注意事项的警告只针对测试方法部分，即该规范的14-18章节：该标准并不旨在提出所有的安全问题，如果有的话，与其使用相关。

该标准的使用者有责任建立安全健康的实验并在使用前确定规则限制的适用性。

2.相关文献2.1美国材料试验学会标准：A380对不锈钢部件，设备和ASTM年度图书卷01.03.中材料的清洗，除锈及去钝化的实验B117对ASTM年度图书卷03.02.中材料进行喷盐（雾化）的实验C254对不锈钢材料（ASTM年度图书卷02.05.中材料）编制及电镀的实验2.2联邦的规范标准：QQ-P-35C耐腐蚀钢材的钝化处理方法3.术语3.1该标准特定的术语定义-在该标准规范中定义常用的术语passivation是必要的（详见讨论）。

3.1.1讨论-如果不锈钢暴露在空气或潮湿的环境下产生了防钝化膜，它会自动钝化。

不锈钢容器零部件酸洗钝化工艺守则1、总则本工艺守则规定不锈钢容器、零部件采用酸洗钝化膏进行酸洗钝化的工艺要求。

2、产品零部件酸洗，钝化前表面质量要求：2.1 焊缝表面熔渣，飞溅物必须去除干净。

2.2 焊接热影响区表面及热加工表面的氧化皮要清理干净。

2.3 表面严重划伤，砂轮磨痕等应用钢砂打磨干净，然后用抛光机进行局部抛光。

2.4 表面不得有明显的凹坑，如凹坑深度大于0.5mm 须补焊。

3、表面处理(酸洗、钝化)工艺流程：去灰尘(用冷水冲洗)--去油污(按工艺规程)--冲洗(用冷水或热水冲洗)--酸洗钝化(按工艺规程)--冲洗(用冷水或热水冲洗)--消除残存氧化物和焊接飞溅物。

检验--钝化(按工艺规程)--冲洗(用冷水或热水冲洗)中和--检验。

去油污时用纱布或棉纱蘸汽油或四氯化碳擦拭酸洗零部件的全部表面，一般需擦两遍，对油污多的地方擦干净为止。

4、酸洗钝化一体化处理酸洗钝化膏配制如下硝酸(HNO3) 20%氢氟酸(HF) 10%水(H2O) 70%说明：先按配方配制溶液，并在室温时浸洗，时间为15～30 分钟，取出后用清水冲洗干净。

5、酸洗表面质量要求5.1 酸洗过程中不得有明显的腐蚀痕迹；5.2 表面不得留有颜色不均匀的斑纹；5.3 不锈钢表面不得粘有碳钢微粒。

5.4 酸洗钝化质量检查方法5.4.1 肉眼检查：检查上述5.1～5.3 项要求；5.4.2 检查不锈钢表面是否粘有碳钢微粒：用8 克硫酸铜溶于500ml 水中，加入2～3ml 硫酸，滴此液于工件表面，保持湿态，如在 6 分钟内不出现钢的析出即认为合格。

6、钝化质量检测如图样要求用兰点检查时，按下列方法进行：1克赤血盐＋3ml65～85%浓度的HNO3＋100ml 水配置溶液，用滤纸浸渍溶液后，贴附在待检表面，也可直接将溶液涂刷于待检表面。

如表面钝化膜不完善或铁离子污染，即呈兰色。

7、表面残余酸性检验经处理后，不锈钢零部件表面不得有残酸，检查时可将PH 试纸蘸水贴在工件表面，试纸颜色不变红即为合格。