(technology tips)
Erlykin L.A. DIY 3-92
Before any of the home craftsmen did not get up the need to nickel or chrome this or that part. What do-it-yourselfer did not dream of installing a “non-working” bushing with a hard, wear-resistant surface obtained by saturating it with boron in a critical node. But how to do at home what, as a rule, is carried out at specialized enterprises by methods of chemical-thermal and electrochemical processing of metals. You will not build gas and vacuum furnaces at home, or build electrolysis baths. But it turns out that it is not necessary to build all this at all. It is enough to have some reagents on hand, an enamel pan and, perhaps, a blowtorch, and also know the recipes for “chemical technology”, with which metals can also be copper-plated, cadmium, tinned, oxidized, etc.
So, let's start getting acquainted with the secrets of chemical technology. Please note that the contents of the components in the solutions given are usually given in g/l. If other units are used, a special clause follows.
Preparatory operations
Before applying paints, protective and decorative films, and also before coating them with other metals, it is necessary to carry out preparatory operations, that is, to remove contamination from these surfaces different nature. Please note that the final result of all work depends to a large extent on the quality of the preparatory operations.
Preparatory operations include degreasing, cleaning and pickling.
Degreasing
The process of degreasing the surface of metal parts is carried out, as a rule, when these parts have just been processed (ground or polished) and there are no rust, scale and other foreign products on their surface.
With the help of degreasing, oil and grease films are removed from the surface of the parts. For this, aqueous solutions of some chemicals are used, although organic solvents can also be used for this. The latter have the advantage that they do not have a subsequent corrosive effect on the surface of the parts, but they are toxic and flammable.
aqueous solutions. Degreasing of metal parts in aqueous solutions is carried out in enameled dishes. Pour water, dissolve chemicals in it and put on a small fire. When the desired temperature is reached, the parts are loaded into the solution. During processing, the solution is stirred. Below are the compositions of the degreasing solutions (g/l), as well as the operating temperatures of the solutions and the processing time of the parts.
Compositions of degreasing solutions (g/l)
For ferrous metals (iron and iron alloys)
Liquid glass (stationery silicate glue) - 3 ... 10, caustic soda (potassium) - 20 ... 30, trisodium phosphate - 25 ... 30. Solution temperature - 70...90°C, processing time - 10...30 min.
Liquid glass - 5 ... 10, caustic soda - 100 ... 150, soda ash - 30 ... 60. Solution temperature - 70...80°C, processing time - 5...10 min.
Liquid glass - 35, trisodium phosphate - 3 ... 10. Solution temperature - 70...90°С, processing time - 10...20 min.
Liquid glass - 35, trisodium phosphate - 15, preparation - emulsifier OP-7 (or OP-10) -2. Solution temperature - 60-70°С, processing time - 5...10 min.
Liquid glass - 15, preparation OP-7 (or OP-10) -1. Solution temperature - 70...80°С, processing time - 10...15 min.
Soda ash - 20, potassium chromium peak - 1. Solution temperature - 80 ... 90 ° C, processing time - 10 ... 20 minutes.
Soda ash - 5 ... 10, trisodium phosphate - 5 ... 10, preparation OP-7 (or OP-10) - 3. Solution temperature - 60 ... 80 ° C, processing time - 5 ... 10 min .
For copper and copper alloys
Caustic soda - 35, soda ash - 60, trisodium phosphate - 15, preparation OP-7 (or OP-10) - 5. Solution temperature - 60 ... 70, processing time - 10 ... 20 minutes.
Caustic soda (potassium) - 75, liquid glass- 20 Solution temperature - 80...90°С, processing time - 40...60 min.
Liquid glass - 10 ... 20, trisodium phosphate - 100. Solution temperature - 65 ... 80 C, processing time - 10 ... 60 minutes.
Liquid glass - 5 ... 10, soda ash - 20 ... 25, preparation OP-7 (or OP-10) - 5 ... 10. Solution temperature - 60...70°С, processing time - 5...10 min.
Trisodium phosphate - 80...100. Solution temperature - 80...90°С, processing time - 30...40 min.
For aluminum and its alloys
Liquid glass - 25...50, soda ash - 5...10, trisodium phosphate-5...10, preparation OP-7 (or OP-10) - 15...20 min.
Liquid glass - 20 ... 30, soda ash - 50 ... 60, trisodium phosphate - 50 ... 60. Solution temperature - 50…60°С, processing time - 3...5 min.
Soda ash - 20 ... 25, trisodium phosphate - 20 ... 25, preparation OP-7 (or OP-10) - 5 ... 7. Temperature - 70...80°С, processing time - 10...20 min.
For silver, nickel and their alloys
Liquid glass - 50, soda ash - 20, trisodium phosphate - 20, preparation OP-7 (or OP-10) - 2. Solution temperature - 70 ... 80 ° C, processing time - 5 ... 10 minutes.
Liquid glass - 25, soda ash - 5, trisodium phosphate - 10. Solution temperature - 75 ... 85 ° C, processing time - 15 ... 20 minutes.
For zinc
Liquid glass - 20 ... 25, caustic soda - 20 ... 25, soda ash - 20 ... 25. Solution temperature - 65...75°С, processing time - 5 min.
Liquid glass - 30...50, soda ash - 30..,50, kerosene - 30...50, preparation OP-7 (or OP-10) - 2...3. Solution temperature - 60-70°С, processing time - 1...2 min.
organic solvents
The most commonly used organic solvents are B-70 gasoline (or "lighter gasoline") and acetone. However, they have a significant drawback - they are easily ignited. Therefore, in Lately they are being replaced by non-flammable solvents such as trichlorethylene and perchlorethylene. Their dissolving power is much higher than that of gasoline and acetone. Moreover, these solvents can be fearlessly heated, which greatly accelerates the degreasing of metal parts.
Degreasing the surface of metal parts with organic solvents is carried out in the following sequence. The parts are loaded into a container with a solvent and incubated for 15 ... 20 minutes. Then the surface of the parts is wiped directly in the solvent with a brush. After such treatment, the surface of each part is carefully treated with a swab moistened with 25% ammonia (it is necessary to work with rubber gloves!).
All degreasing work organic solvents carried out in a well-ventilated area.
cleaning
In this section, as an example, the decarbonization process of internal combustion engines will be considered. As you know, carbon deposits are asphalt-resinous substances that form hard-to-remove films on the working surfaces of engines. Removing carbon deposits is a rather difficult task, since the carbon film is inert and firmly adhered to the surface of the part.
Compositions of cleaning solutions (g/l)
For ferrous metals
Liquid glass - 1.5, soda ash - 33, caustic soda - 25, laundry soap - 8.5. Solution temperature - 80...90°C, processing time - Zh.
Caustic soda - 100, potassium bichromate - 5. Solution temperature - 80 ... 95 ° C, processing time - up to 3 hours.
Caustic soda - 25, liquid glass - 10, sodium bichromate - 5, laundry soap- 8, soda ash - 30. Solution temperature - 80 ... 95 ° C, processing time - up to 3 hours.
Caustic soda - 25, liquid glass - 10, laundry soap - 10, potash - 30. Solution temperature - 100 ° C, processing time - up to 6 hours.
For aluminum (duralumin) alloys
Liquid glass 8.5, laundry soap - 10, soda ash - 18.5. Solution temperature - 85...95 C, processing time - up to 3 hours.
Liquid glass - 8, potassium dichromate - 5, laundry soap - 10, soda ash - 20. Solution temperature - 85 ... 95 ° C, processing time - up to 3 hours.
Soda ash - 10, potassium bichromate - 5, laundry soap - 10. Solution temperature - 80 ... 95 ° C, processing time - up to 3 hours.
Etching
Etching (as a preparatory operation) makes it possible to remove contaminants firmly adhered to their surface (rust, scale and other corrosion products) from metal parts.
The main purpose of etching is the removal of corrosion products; while the base metal should not be etched. To prevent metal etching, special additives are introduced into the solutions. Good results gives the use of small amounts of hexamethylenetetramine (urotropine). In all solutions for etching ferrous metals, add 1 tablet (0.5 g) of urotropine per 1 liter of solution. In the absence of urotropin, it is replaced with the same amount of dry alcohol (sold in sports stores as fuel for tourists).
In view of the fact that inorganic acids are used in recipes for etching, it is necessary to know their initial density (g / cm 3): nitric acid - 1.4, sulfuric acid - 1.84; hydrochloric acid - 1.19; orthophosphoric acid- 1.7; acetic acid - 1.05.
Compositions of solutions for etching
For ferrous metals
Sulfuric acid - 90...130, hydrochloric acid - 80...100. Solution temperature - 30...40°С, processing time - 0.5...1.0 h.
Sulfuric acid - 150...200. Solution temperature - 25...60°С, processing time - 0.5...1.0 h.
Hydrochloric acid - 200. Solution temperature - 30...35°С, processing time - 15...20 min.
Hydrochloric acid - 150 ... 200, formalin - 40 ... 50. Solution temperature 30...50°C, treatment time 15...25 min.
Nitric acid - 70...80, hydrochloric acid - 500...550. Solution temperature - 50°С, processing time - 3...5 min.
Nitric acid - 100, sulfuric acid - 50, hydrochloric acid - 150. Solution temperature - 85°C, processing time - 3...10 min.
Hydrochloric acid - 150, phosphoric acid - 100. Solution temperature - 50°C, processing time - 10...20 min.
The last solution (when processing steel parts), in addition to cleaning the surface, also phosphates it. And phosphate films on the surface of steel parts make it possible to paint them with any paint without a primer, since these films themselves serve as an excellent primer.
Here are a few more recipes for etching solutions, the compositions of which this time are given in% (by weight).
Orthophosphoric acid - 10, butyl alcohol - 83, water - 7. Solution temperature - 50...70°C, processing time - 20...30 min.
Orthophosphoric acid - 35, butyl alcohol - 5, water - 60. Solution temperature - 40...60°C, processing time - 30...35 min.
After etching of ferrous metals, they are washed in a 15% solution of soda ash (or drinking) soda. Then rinse thoroughly with water.
Note that below the compositions of the solutions are again given in g/L.
For copper and its alloys
Sulfuric acid - 25...40, chromic anhydride - 150...200. Solution temperature - 25°С, processing time - 5...10 min.
Sulfuric acid - 150, potassium bichromate - 50. Solution temperature - 25.35°C, processing time - 5...15 min.
Trilon B-100. Solution temperature - 18...25°C, processing time - 5...10 min.
Chromic anhydride - 350, sodium chloride - 50. Solution temperature - 18...25°С, processing time - 5...15 min.
For aluminum and its alloys
Caustic soda -50...100. Solution temperature - 40...60°С, treatment time - 5...10 s.
Nitric acid - 35...40. Solution temperature - 18...25°С, treatment time - 3...5 s.
Caustic soda - 25 ... 35, soda ash - 20 ... 30. Solution temperature - 40...60°С, treatment time - 0.5...2.0 min.
Caustic soda - 150, sodium chloride - 30. Solution temperature - 60°C, processing time - 15 ... 20 s.
Chemical polishing
Chemical polishing allows you to quickly and efficiently process the surface of metal parts. Big Advantage This technology lies in the fact that with the help of it (and only it!) It is possible to polish parts with a complex profile at home.
Compositions of solutions for chemical polishing
For carbon steels (the content of components is indicated in each case in certain units (g / l, percent, parts)
Nitric acid - 2.-.4, hydrochloric acid 2 ... 5, Orthophosphoric acid - 15 ... 25, the rest is water. Solution temperature - 70...80°С, processing time - 1...10 min. The content of the components - in% (by volume).
Sulfuric acid - 0.1, acetic acid - 25, hydrogen peroxide (30%) - 13. Solution temperature - 18 ... 25 ° C, processing time - 30 ... 60 minutes. Content of components - in g/l.
Nitric acid - 100...200, sulfuric acid - 200..,600, hydrochloric acid - 25, Orthophosphoric acid - 400. Mixture temperature - 80...120°С, treatment time - 10...60 s. Content of components in parts (by volume).
For stainless steel
Sulfuric acid - 230, hydrochloric acid - 660, acid orange dye - 25. Solution temperature - 70...75°С, processing time - 2...3 min. Content of components - in g/l.
Nitric acid - 4 ... 5, hydrochloric acid - 3 ... 4, Orthophosphoric acid - 20..30, methyl orange - 1..1.5, the rest is water. Solution temperature - 18...25°С, treatment time - 5..10 min. The content of the components - in% (by weight).
Nitric acid - 30...90, potassium ferricyanide (yellow blood salt) - 2...15 g/l, preparation OP-7 - 3...25, hydrochloric acid - 45..110, phosphoric acid - 45. ..280.
Solution temperature - 30...40°С, processing time - 15...30 min. The content of components (except for yellow blood salt) - in pl / l.
The latter composition is applicable for polishing cast iron and any steels.
For copper
Nitric acid - 900, sodium chloride - 5, carbon black - 5. Solution temperature - 18 ... 25 ° C, processing time - 15 ... 20 s. Content of components - g/l.
Attention! Sodium chloride is added to solutions last, and the solution must be pre-cooled!
Nitric acid - 20, sulfuric acid - 80, hydrochloric acid - 1, chromic anhydride - 50. Solution temperature - 13..18°C, processing time - 1...2 min. Content of components - in ml.
Nitric acid 500, sulfuric acid - 250, sodium chloride - 10. Solution temperature - 18 ... 25 ° C, processing time - 10 ... 20 s. Content of components - in g/l.
For brass
Nitric acid - 20, hydrochloric acid - 0.01, acetic acid - 40, phosphoric acid - 40. Mixture temperature - 25...30°C, processing time - 20...60 s. Content of components - in ml.
Sulphate copper ( blue vitriol) - 8, sodium chloride - 16, acetic acid - 3, water - the rest. Solution temperature - 20°С, processing time - 20...60 min. The content of components - in% (by weight).
For bronze
Orthophosphoric acid - 77 ... 79, potassium nitrate - 21 ... 23. Mixture temperature - 18°C, processing time - 0.5-3 min. The content of components - in% (by weight).
Nitric acid - 65, sodium chloride - 1 g, acetic acid - 5, orthophosphoric acid - 30, water - 5. Solution temperature - 18 ... 25 ° C, processing time - 1 ... 5 s. The content of components (except sodium chloride) - in ml.
For nickel and its alloys (cupronickel and nickel silver)
Nitric acid - 20, acetic acid - 40, phosphoric acid - 40. Mixture temperature - 20°C, processing time - up to 2 minutes. The content of components - in% (by weight).
Nitric acid - 30, acetic acid (glacial) - 70. Mixture temperature - 70...80°С, treatment time - 2...3 s. The content of components - in% (by volume).
For aluminum and its alloys
Orthophosphoric acid - 75, sulfuric acid - 25. Mixture temperature - 100°C, processing time - 5...10 min. The content of components - in parts (by volume).
Orthophosphoric acid - 60, sulfuric acid - 200, nitric acid - 150, urea - 5g. The temperature of the mixture is 100°C, the processing time is 20 s. The content of components (except urea) - in ml.
Orthophosphoric acid - 70, sulfuric acid - 22, boric acid - 8. Mixture temperature - 95°C, processing time - 5...7 min. The content of components - in parts (by volume).
Passivation
Passivation is the process of chemically creating an inert layer on the surface of a metal, which prevents the metal itself from oxidizing. Surface passivation process metal products chasers use when creating their works; craftsmen - in the manufacture various crafts(chandeliers, sconces and other household items); sports anglers passivate their homemade metal lures.
Compositions of solutions for passivation (g/l)
For ferrous metals
Sodium nitrite - 40...100. Solution temperature - 30...40°С, processing time - 15...20 min.
Sodium nitrite - 10...15, soda ash - 3...7. Solution temperature - 70...80°С, processing time - 2...3 min.
Sodium nitrite - 2...3, soda ash - 10, preparation OP-7 - 1...2. Solution temperature - 40...60°С, processing time - 10...15 min.
Chromic anhydride - 50. Solution temperature - 65 ... 75 "C, processing time - 10 ... 20 minutes.
For copper and its alloys
Sulfuric acid - 15, potassium bichromate - 100. Solution temperature - 45°C, processing time - 5...10 min.
Potassium dichromate - 150. Solution temperature - 60°C, processing time - 2...5 min.
For aluminum and its alloys
Orthophosphoric acid - 300, chromic anhydride - 15. Solution temperature - 18...25°C, processing time - 2...5 min.
Potassium dichromate - 200. Solution temperature - 20°C, "treatment time -5...10 min.
For silver
Potassium dichromate - 50. Solution temperature - 25 ... 40 ° C, processing time - 20 minutes.
For zinc
Sulfuric acid - 2...3, chromic anhydride - 150...200. Solution temperature - 20°С, processing time - 5...10 s.
Phosphating
As already mentioned, the phosphate film on the surface of steel parts is a fairly reliable anti-corrosion coating. It is also an excellent primer for paintwork.
Some low-temperature phosphating methods are applicable to bodywork cars before coating them with anti-corrosion and anti-wear compounds.
Compositions of solutions for phosphating (g/l)
For steel
Mazhef (phosphate salts of manganese and iron) - 30, zinc nitrate - 40, sodium fluoride - 10. Solution temperature - 20 ° C, processing time - 40 minutes.
Monozinc phosphate - 75, zinc nitrate - 400 ... 600. Solution temperature - 20°С, processing time - 20...30 s.
Majef - 25, zinc nitrate - 35, sodium nitrite - 3. Solution temperature - 20°C, processing time - 40 min.
Monoammonium phosphate - 300. Solution temperature - 60 ... 80 ° C, processing time - 20 ... 30 s.
Phosphoric acid - 60...80, chromic anhydride - 100...150. Solution temperature - 50...60°С, processing time - 20...30 min.
Orthophosphoric acid - 400 ... 550, butyl alcohol - 30. Solution temperature - 50 ° C, processing time - 20 minutes.
Application metal coatings
The chemical coating of some metals with others captivates with its simplicity technological process. Indeed, if, for example, it is necessary to chemically nickel plate some steel part, it is enough to have suitable enameled dishes, a heating source ( gas stove, primus, etc.) and relatively non-deficient chemicals. An hour or two - and the part is covered with a shiny layer of nickel.
Note that only with the help of chemical nickel plating it is possible to reliably nickel-plating parts of a complex profile, internal cavities (pipes, etc.). True, chemical nickel plating (and some other similar processes) is not without its drawbacks. The main one is not too strong adhesion of the nickel film to the base metal. However, this drawback can be eliminated; for this, the so-called low-temperature diffusion method is used. It allows you to significantly increase the adhesion of the nickel film to the base metal. This method is applicable to all chemical coatings of some metals by others.
nickel plating
The process of chemical nickel plating is based on the reaction of nickel reduction from aqueous solutions of its salts using sodium hypophosphite and some other chemicals.
Nickel coatings obtained by chemical means have an amorphous structure. The presence of phosphorus in nickel makes the film close in hardness to a chromium film. Unfortunately, the adhesion of the nickel film to the base metal is relatively low. Heat treatment of nickel films (low-temperature diffusion) consists in heating nickel-plated parts to a temperature of 400°C and keeping them at this temperature for 1 hour.
If nickel-plated parts are hardened (springs, knives, fish hooks, etc.), then at a temperature of 40 ° C they can be released, that is, they can lose their main quality - hardness. In this case, low-temperature diffusion is carried out at a temperature of 270...300 C with an exposure of up to 3 hours. In this case, the heat treatment also increases the hardness of the nickel coating.
All the listed advantages of chemical nickel plating did not escape the attention of technologists. They found them practical use(except for the use of decorative and anti-corrosion properties). So, with the help of chemical nickel plating, the axes of various mechanisms, worms of thread-cutting machines, etc. are repaired.
At home, with the help of nickel plating (of course, chemical!) You can repair parts of various household devices. The technology here is extremely simple. For example, the axis of a device was demolished. Then they build up (with excess) a layer of nickel on the damaged area. Then the working section of the axis is polished, bringing it to the desired size.
It should be noted that chemical nickel plating cannot cover metals such as tin, lead, cadmium, zinc, bismuth and antimony.
Solutions used for chemical nickel plating are divided into acidic (pH - 4 ... 6.5) and alkaline (pH - above 6.5). Acidic solutions are preferably used for coating ferrous metals, copper and brass. Alkaline - for stainless steels.
Acidic solutions (compared to alkaline ones) on a polished part give a smoother (mirror-like) surface, they have less porosity, and the speed of the process is higher. Another important feature of acidic solutions is that they are less likely to self-discharge when the operating temperature is exceeded. (Self-discharge - instantaneous precipitation of nickel into a solution with splashing of the latter.)
In alkaline solutions, the main advantage is a more reliable adhesion of the nickel film to the base metal.
And the last. Water for nickel plating (and when applying other coatings) is taken distilled (you can use condensate from household refrigerators). Chemical reagents are suitable at least pure (designation on the label - H).
Before coating parts with any metal film, it is necessary to conduct a special preparation of their surface.
Preparation of all metals and alloys is as follows. The treated part is degreased in one of the aqueous solutions, and then the part is decapitated in one of the solutions listed below.
Compositions of solutions for decapitation (g/l)
For steel
Sulfuric acid - 30...50. Solution temperature - 20°С, processing time - 20...60 s.
Hydrochloric acid - 20...45. Solution temperature - 20°С, treatment time - 15...40 s.
Sulfuric acid - 50...80, hydrochloric acid - 20...30. Solution temperature - 20°С, processing time - 8...10 s.
For copper and its alloys
Sulfuric acid - 5% solution. Temperature - 20°C, processing time - 20s.
For aluminum and its alloys
Nitric acid. (Attention, 10 ... 15% solution.) Solution temperature - 20 ° C, processing time - 5 ... 15 s.
Please note that for aluminum and its alloys before chemical nickel plating carry out another processing - the so-called zincate. Below are solutions for zincate treatment.
For aluminum
Caustic soda - 250, zinc oxide - 55. Solution temperature - 20 C, treatment time - 3 ... 5s.
Caustic soda - 120, zinc sulfate - 40. Solution temperature - 20 ° C, processing time - 1.5 ... 2 minutes.
When preparing both solutions, first, caustic soda is dissolved separately in half of the water, and the zinc component in the other half. Then both solutions are poured together.
For cast aluminum alloys
Caustic soda - 10, zinc oxide - 5, Rochelle salt (crystal hydrate) - 10. Solution temperature - 20 C, processing time - 2 minutes.
For wrought aluminum alloys
Ferric chloride (crystal hydrate) - 1, sodium hydroxide - 525, zinc oxide 100, Rochelle salt - 10. Solution temperature - 25 ° C, processing time - 30 ... 60 s.
After zincate treatment, the parts are washed in water and hung in a nickel plating solution.
All solutions for nickel plating are universal, that is, they are suitable for all metals (although there are some specifics). Prepare them in a certain sequence. So, all chemicals (except sodium hypophosphite) are dissolved in water (enamelled dishes!). Then the solution is heated to the operating temperature and only after that sodium hypophosphite is dissolved and the parts are hung into the solution.
In 1 liter of solution, a surface up to 2 dm2 in area can be nickel plated.
Compositions of solutions for nickel plating (g/l)
Nickel sulphate - 25, sodium succinic acid - 15, sodium hypophosphite - 30. Solution temperature - 90°C, pH - 4.5, film growth rate - 15...20 µm/h.
Nickel chloride - 25, sodium succinic acid - 15, sodium hypophosphite - 30. Solution temperature - 90 ... 92 ° C, pH - 5.5, growth rate - 18 ... 25 μm / h.
Nickel chloride - 30, glycolic acid - 39, sodium hypophosphite - 10. Solution temperature 85..89°С, pH - 4.2, growth rate - 15...20 µm/h.
Nickel chloride - 21, sodium acetate - 10, sodium hypophosphite - 24, Solution temperature - 97 ° C, pH - 5.2, growth rate - up to 60 μm / h.
Nickel sulfate - 21, sodium acetate - 10, lead sulfide - 20, sodium hypophosphite - 24. Solution temperature - 90 ° C, pH - 5, growth rate - up to 90 μm / h.
Nickel chloride - 30, acetic acid - 15, lead sulfide - 10 ... 15, sodium hypophosphite - 15. Solution temperature - 85 ... 87 ° C, pH - 4.5, growth rate - 12 ... 15 microns /h
Nickel chloride - 45, ammonium chloride - 45, sodium citrate - 45, sodium hypophosphite - 20. Solution temperature - 90 ° C, pH - 8.5, growth rate - 18 ... 20 microns / h.
Nickel chloride - 30, ammonium chloride - 30, sodium succinic acid - 100, ammonia (25% solution - 35, sodium hypophosphite - 25).
Temperature - 90°C, pH - 8...8.5, growth rate - 8...12 µm/h.
Nickel chloride - 45, ammonium chloride - 45, sodium acetate - 45, sodium hypophosphite - 20. Solution temperature - 88 .... 90 ° C, pH - 8 ... 9, growth rate - 18 ... 20 microns / h.
Nickel sulphate - 30, ammonium sulphate - 30, sodium hypophosphite - 10. Solution temperature - 85°C, pH - 8.2...8.5, growth rate - 15...18 µm/h.
Attention! According to existing state standards, a single-layer nickel coating per 1 cm2 has several tens of through (to the base metal) pores. Naturally, on outdoors a steel part plated with nickel will quickly become covered with a "rash" of rust.
In a modern car, for example, the bumper is covered with a double layer (a sublayer of copper, and chrome on top) and even a triple layer (copper - nickel - chrome). But even this does not save the part from rust, since according to GOST and the triple coating has several pores per 1 cm2. What to do? The way out is in the surface treatment of the coating with special compounds that close the pores.
Wipe the part with a nickel (or other) coating with a slurry of magnesium oxide and water and immediately lower it for 1 ... 2 minutes in a 50% hydrochloric acid solution.
After heat treatment, lower the part that has not yet cooled down into non-vitaminized fish oil (preferably old, unsuitable for its intended purpose).
Wipe the nickel-plated surface of the part 2...3 times with the composition of LPS (easy penetrating lubricant).
In the last two cases, excess fat (grease) is removed from the surface with gasoline in a day.
The treatment of large surfaces (bumpers, car moldings) with fish oil is carried out as follows. In hot weather, wipe them with fish oil twice with a break of 12-14 hours. Then, after 2 days, excess fat is removed with gasoline.
The effectiveness of such processing is characterized by the following example. Nickel-plated fishing hooks begin to rust immediately after the first sea fishing. The same hooks treated with fish oil do not corrode for almost the entire summer sea fishing season.
Chrome plating
Chemical chromium plating allows you to get a coating on the surface of metal parts gray color, which after polishing acquires the desired shine. Chrome adheres well to nickel plating. The presence of phosphorus in chemically produced chromium greatly increases its hardness. Heat treatment for chrome plating is essential.
Below are tried and tested recipes. chemical chromium plating.
Compositions of solutions for chemical chromium plating (g/l)
Chromium fluoride - 14, sodium citrate - 7, acetic acid - 10 ml, sodium hypophosphite - 7. Solution temperature - 85 ... 90 ° C, pH - 8 ... 11, growth rate - 1.0 ... 2 .5 µm/h.
Chromium fluoride - 16, chromium chloride - 1, sodium acetate - 10, sodium oxalate - 4.5, sodium hypophosphite - 10. Solution temperature - 75 ... 90 ° C, pH - 4 ... 6, growth rate - 2 ...2.5 µm/h.
Chromium fluoride - 17, chromium chloride - 1.2, sodium citrate - 8.5, sodium hypophosphite - 8.5. Solution temperature - 85...90°C, pH - 8...11, growth rate - 1...2.5 µm/h.
Chromium acetate - 30, nickel acetate - 1, sodium glycolate - 40, sodium acetate - 20, sodium citrate - 40, acetic acid - 14 ml, sodium hydroxide - 14, sodium hypophosphite - 15. Solution temperature - 99 ° C, pH - 4...6, growth rate - up to 2.5 µm/h.
Chromium fluoride - 5 ... 10, chromium chloride - 5 ... 10, sodium citrate - 20 ... 30, sodium pyrophosphate (replacing sodium hypophosphite) - 50 ... 75.
Solution temperature - 100°C, pH - 7.5...9, growth rate - 2...2.5 µm/h.
Boronickel plating
The film of this double alloy has increased hardness (especially after heat treatment), high temperature melting, high wear resistance and significant corrosion resistance. All this makes it possible to use such a coating in various responsible makeshift designs. Below are the recipes for solutions in which boronickeling is carried out.
Compositions of solutions for chemical boron nickel plating (g/l)
Nickel chloride - 20, sodium hydroxide - 40, ammonia (25% solution): - 11, sodium borohydride - 0.7, ethylenediamine (98% solution) - 4.5. Solution temperature - 97°C, growth rate - 10 µm/h.
Nickel sulfate - 30, triethylsyntetramine - 0.9, sodium hydroxide - 40, ammonia (25% solution) - 13, sodium borohydride - 1. Solution temperature - 97 C, growth rate - 2.5 μm / h.
Nickel chloride - 20, sodium hydroxide - 40, Rochelle salt - 65, ammonia (25% solution) - 13, sodium borohydride - 0.7. Solution temperature - 97°C, growth rate - 1.5 µm/h.
Caustic soda - 4 ... 40, potassium metabisulphite - 1 ... 1.5, potassium sodium tartrate - 30 ... 35, nickel chloride - 10 ... 30, ethylenediamine (50% solution) - 10 ... 30 , sodium borohydride - 0.6 ... 1.2. Solution temperature - 40...60°C, growth rate - up to 30 µm/h.
Solutions are prepared in the same way as for nickel plating: first, everything except sodium borohydride is dissolved, the solution is heated and sodium borohydride is dissolved.
Borocobalting
The use of this chemical process makes it possible to obtain a film of particularly high hardness. It is used to repair friction pairs, where increased wear resistance of the coating is required.
Compositions of solutions for boron cobalt treatment (g/l)
Cobalt chloride - 20, sodium hydroxide - 40, sodium citrate - 100, ethylenediamine - 60, ammonium chloride - 10, sodium borohydride - 1. Solution temperature - 60 ° C, pH - 14, growth rate - 1.5 .. .2.5 µm/h.
Cobalt acetate - 19, ammonia (25% solution) - 250, potassium tartrate - 56, sodium borohydride - 8.3. Solution temperature - 50°С, pH - 12.5, growth rate - 3 µm/h.
Cobalt sulphate - 180, boric acid - 25, dimethylborazan - 37. Solution temperature - 18°C, pH - 4, growth rate - 6 µm/h.
Cobalt chloride - 24, ethylenediamine - 24, dimethylborazan - 3.5. Solution temperature - 70 C, pH - 11, growth rate - 1 µm/h.
The solution is prepared in the same way as boronickel.
Cadmium plating
On the farm, it is often necessary to use fasteners coated with cadmium. This is especially true for parts that are operated outdoors.
It is noted that chemically obtained cadmium coatings adhere well to the base metal even without heat treatment.
Cadmium chloride - 50, ethylenediamine - 100. Cadmium should be in contact with parts (suspension on cadmium wire, small parts are sprinkled with cadmium powder). Solution temperature - 65°C, pH - 6...9, growth rate - 4 µm/h.
Attention! Ethylenediamine is dissolved last in the solution (after heating).
copper plating
Chemical copper plating is most often used in the manufacture of printed circuit boards for radio electronics, in electroforming, for metallization of plastics, for double coating of some metals with others.
Compositions of solutions for copper plating (g/l)
Copper sulphate - 10, sulfuric acid - 10. Solution temperature - 15...25°C, growth rate - 10 µm/h.
Potassium-sodium tartrate - 150, copper sulphate - 30, caustic soda - 80. Solution temperature - 15 ... 25 ° C, growth rate - 12 μm / h.
Copper sulphate - 10 ... 50, caustic soda - 10 ... 30, Rochelle salt 40 ... 70, formalin (40% solution) - 15 ... 25. Solution temperature - 20°C, growth rate - 10 µm/h.
Sulfuric copper - 8...50, sulfuric acid - 8...50. Solution temperature - 20°C, growth rate - 8 µm/h.
Copper sulphate - 63, potassium tartrate - 115, sodium carbonate - 143. Solution temperature - 20 C, growth rate - 15 µm/h.
Copper sulphate - 80 ... 100, caustic soda - 80 ..., 100, sodium carbonate - 25 ... 30, nickel chloride - 2 ... 4, Rochelle salt - 150 ... 180, formalin (40% - solution) - 30...35. Solution temperature - 20°C, growth rate - 10 µm/h. This solution makes it possible to obtain films with a low nickel content.
Copper sulfate - 25 ... 35, sodium hydroxide - 30 ... 40, sodium carbonate - 20-30, trilon B - 80 ... 90, formalin (40% solution) - 20 ... 25, rhodanine - 0.003 ... 0.005, potassium ferricyanide (red blood salt) - 0.1..0.15. Solution temperature - 18...25°C, growth rate - 8 µm/h.
This solution is highly stable over time and makes it possible to obtain thick copper films.
To improve the adhesion of the film to the base metal, heat treatment is the same as for nickel.
Silvering
Silvering metal surfaces, perhaps the most popular process among craftsmen, which they use in their activities. Dozens of examples could be given. For example, restoration of the silver layer on cupronickel cutlery, silvering of samovars and other household items.
For chasers, silvering, together with chemical coloring of metal surfaces (it will be discussed below), is a way to increase the artistic value of chased paintings. Imagine a minted ancient warrior with silver plated chain mail and a helmet.
The process itself chemical silvering can be carried out using solutions and pastes. The latter is preferable when processing large surfaces (for example, when silvering samovars or parts of large chased paintings).
Composition of solutions for silvering (g/l)
Silver chloride - 7.5, potassium ferricyanide - 120, potassium carbonate - 80. The temperature of the working solution is about 100 ° C. Processing time - until the desired thickness of the silver layer is obtained.
Silver chloride - 10, sodium chloride - 20, acid potassium tartrate - 20. Processing - in a boiling solution.
Silver chloride - 20, potassium ferricyanide - 100, potassium carbonate - 100, ammonia (30% solution) - 100, sodium chloride - 40. Processing - in a boiling solution.
First, a paste is prepared from silver chloride - 30 g, tartaric acid - 250 g, sodium chloride - 1250, and everything is diluted with water to the density of sour cream. 10 ... 15 g of paste is dissolved in 1 liter of boiling water. Processing - in a boiling solution.
Details are hung in solutions for silvering on zinc wires (strips).
The processing time is determined visually. It should be noted here that brass is better silvered than copper. On the latter, it is necessary to apply a rather thick layer of silver so that dark copper does not shine through the coating layer.
One more note. Solutions with silver salts cannot be stored for a long time, as explosive components can be formed in this case. The same applies to all liquid pastes.
Compositions of pastes for silvering.
In 300 ml warm water dissolve 2 g of lapis pencil (sold in pharmacies, it is a mixture of silver nitrate and amino acid potassium, taken in a ratio of 1: 2 (by weight). A 10% sodium chloride solution is gradually added to the resulting solution until the precipitation stops. silver chloride is filtered off and thoroughly washed in 5-6 waters.
Dissolve 20 g of sodium thiosulfite in 100 ml of water. Silver chloride is added to the resulting solution until it no longer dissolves. The solution is filtered and tooth powder is added to it to the consistency of liquid sour cream. This paste is rubbed (silvered) with a cotton swab.
Lapis pencil - 15, lemon acid(food) - 55, ammonium chloride - 30. Each component is ground into powder before mixing. The content of components - in% (by weight).
Silver chloride - 3, sodium chloride - 3, sodium carbonate - 6, chalk - 2. The content of components - in parts (by weight).
Silver chloride - 3, sodium chloride - 8, potassium tartrate - 8, chalk - 4. Content of components - in parts (by weight).
Silver nitrate - 1, sodium chloride - 2. Content of components - in parts (by weight).
The last four pastes are used as follows. Finely divided components are mixed. With a wet swab, dusting it with a dry mixture of chemicals, rub (silver) desired part. The mixture is added all the time, constantly moistening the swab.
When silvering aluminum and its alloys, the parts are first galvanized and then coated with silver.
Zincate treatment is carried out in one of the following solutions.
Compositions of solutions for zincate treatment (g/l)
For aluminum
Caustic soda - 250, zinc oxide - 55. Solution temperature - 20°C, treatment time - 3...5 s.
Caustic soda - 120, zinc sulfate - 40. Solution temperature - 20°C, processing time - 1.5...2.0 min. To obtain a solution, first caustic soda is dissolved in one half of the water, and zinc sulfate is dissolved in the other. Then both solutions are poured together.
For duralumin
Caustic soda - 10, zinc oxide - 5, Rochelle salt - 10. Solution temperature - 20°C, processing time - 1...2 min.
After zincate treatment, the parts are silvered in any of the above solutions. However, the following solutions (g / l) are considered the best.
Silver nitrate - 100, ammonium fluoride - 100. Solution temperature - 20°C.
Silver fluoride - 100, ammonium nitrate - 100. Solution temperature - 20°C.
Tinning
Chemical tinning of surfaces of parts is used as an anti-corrosion coating and as a preliminary process (for aluminum and its alloys) before soft soldering. Below are compositions for tinning some metals.
Compositions for tinning (g/l)
For steel
Stannous chloride (fused) - 1, ammonia alum - 15. Tinning is carried out in a boiling solution, the growth rate is 5 ... 8 microns / h.
Tin chloride - 10, aluminum-ammonium sulphate - 300. Tinning is carried out in a boiling solution, the growth rate is 5 microns / h.
Stannous chloride - 20, Rochelle salt - 10. Solution temperature - 80°C, growth rate - 3...5 µm/h.
Stannous chloride - 3 ... 4, Rochelle salt - until saturation. Solution temperature - 90...100°C, growth rate - 4...7 µm/h.
For copper and its alloys
Stannous chloride - 1, potassium tartrate - 10. Tinning is carried out in a boiling solution, the growth rate is 10 μm / h.
Stannous chloride - 20, sodium lactate - 200. Solution temperature - 20°C, growth rate - 10 µm/h.
Stannous chloride - 8, thiourea - 40...45, sulfuric acid - 30...40. Solution temperature - 20°C, growth rate - 15 µm/h.
Stannous chloride - 8...20, thiourea - 80...90, hydrochloric acid - 6.5...7.5, sodium chloride - 70...80. Solution temperature - 50...100°C, growth rate - 8 µm/h.
Stannous chloride - 5.5, thiourea - 50, tartaric acid - 35. Solution temperature - 60 ... 70 ° C, growth rate - 5 ... 7 μm / h.
When tinning parts made of copper and its alloys, they are hung on zinc pendants. Small parts“powdered” with zinc filings.
For aluminum and its alloys
The tinning of aluminum and its alloys is preceded by some additional processes. First, the parts degreased with acetone or gasoline B-70 are treated for 5 minutes at a temperature of 70 ° C of the following composition (g / l): sodium carbonate - 56, sodium phosphate - 56. Then the parts are lowered for 30 s into a 50% solution of nitric acid, rinse thoroughly under running water and immediately place in one of the solutions (for tinning) below.
Sodium stannate - 30, sodium hydroxide - 20. Solution temperature - 50...60°C, growth rate - 4 µm/h.
Sodium stannate - 20 ... 80, potassium pyrophosphate - 30 ... 120, sodium hydroxide - 1.5..L, 7, ammonium oxalate - 10 ... 20. Solution temperature - 20...40°C, growth rate - 5 µm/h.
Removal of metal coatings
Usually this process is necessary to remove low-quality metal films or to clean any metal product being restored.
All of the following solutions work faster at elevated temperatures.
Compositions of solutions for removing metal coatings in parts (by volume)
For steel removing nickel from steel
Nitric acid - 2, sulfuric acid - 1, iron sulphate (oxide) - 5 ... 10. The temperature of the mixture is 20°C.
Nitric acid - 8, water - 2. Solution temperature - 20 C.
Nitric acid - 7, acetic acid (glacial) - 3. Mixture temperature - 30°C.
For removing nickel from copper and its alloys (g/l)
Nitrobenzoic acid - 40 ... 75, sulfuric acid - 180. Solution temperature - 80 ... 90 C.
Nitrobenzoic acid - 35, ethylenediamine - 65, thiourea - 5...7. Solution temperature - 20...80°C.
Technical nitric acid is used to remove nickel from aluminum and its alloys. The temperature of the acid is 50°C.
For removing copper from steel
Nitrobenzoic acid - 90, diethylenetriamine - 150, ammonium chloride - 50. Solution temperature - 80°C.
Sodium pyrosulfate - 70, ammonia (25% solution) - 330. Solution temperature - 60 °.
Sulfuric acid - 50, chromic anhydride - 500. Solution temperature - 20°C.
For removing copper from aluminum and its alloys (zinc finish)
Chromic anhydride - 480, sulfuric acid - 40. Solution temperature - 20...70°C.
Technical nitric acid. The temperature of the solution is 50°C.
For removing silver from steel
Nitric acid - 50, sulfuric acid - 850. Temperature - 80°C.
Nitric acid technical. Temperature - 20°C.
Silver is removed from copper and its alloys with technical nitric acid. Temperature - 20°C.
Chrome is removed from steel with a solution of caustic soda (200 g/l). Solution temperature - 20 C.
Chromium is removed from copper and its alloys with 10% hydrochloric acid. The temperature of the solution is 20°C.
Zinc is removed from steel with 10% hydrochloric acid - 200 g / l. The temperature of the solution is 20°C.
Zinc is removed from copper and its alloys with concentrated sulfuric acid. Temperature - 20 C.
Cadmium and zinc are removed from any metals with a solution of aluminum nitrate (120 g/l). The temperature of the solution is 20°C.
Tin from steel is removed with a solution containing sodium hydroxide - 120, nitrobenzoic acid - 30. The temperature of the solution is 20°C.
Tin is removed from copper and its alloys in a solution of ferric chloride - 75 ... 100, copper sulfate - 135 ... 160, acetic acid (glacial) - 175. The temperature of the solution is 20 ° C.
Chemical oxidation and coloring of metals
Chemical oxidation and coloring of the surface of metal parts are intended to create an anti-corrosion coating on the surface of the parts and enhance the decorative effect of the coating.
In ancient times, people already knew how to oxidize their crafts, changing their color (silver blackening, gold coloring, etc.), burn steel objects (heating a steel part to 220 ... 325 ° C, they lubricated it with hemp oil).
Compositions of solutions for oxidation and coloring of steel (g/l)
Note that before oxidation, the part is ground or polished, degreased and decapitated.
Black color
Caustic soda - 750, sodium nitrate - 175. Solution temperature - 135°C, processing time - 90 minutes. The film is dense, shiny.
Caustic soda - 500, sodium nitrate - 500. Solution temperature - 140°C, processing time - 9 minutes. The film is intense.
Caustic soda - 1500, sodium nitrate - 30. Solution temperature - 150°C, processing time - 10 min. The film is matte.
Caustic soda - 750, sodium nitrate - 225, sodium nitrite - 60. Solution temperature - 140 ° C, processing time - 90 minutes. The film is shiny.
Calcium nitrate - 30, phosphoric acid - 1, manganese peroxide - 1. Solution temperature - 100°C, processing time - 45 min. The film is matte.
All of the above methods are characterized by a high working temperature of the solutions, which, of course, does not allow processing large parts. However, there is one "low-temperature solution" suitable for this business (g / l): sodium thiosulfate - 80, ammonium chloride - 60, phosphoric acid - 7, nitric acid - 3. Solution temperature - 20 ° C, processing time - 60 minutes . The film is black, matte.
After oxidation (blackening) of steel parts, they are treated for 15 minutes in a solution of potassium chromium peak (120 g/l) at a temperature of 60°C.
Then the parts are washed, dried and coated with any neutral machine oil.
Blue
Hydrochloric acid - 30, ferric chloride - 30, mercury nitrate - 30, ethyl alcohol - 120. Solution temperature - 20 ... 25 ° C, processing time - up to 12 hours.
Sodium hydrosulphide - 120, lead acetate - 30. Solution temperature - 90...100°C, processing time - 20...30 min.
Blue color
Lead acetate - 15 ... 20, sodium thiosulfate - 60, acetic acid (glacial) - 15 ... 30. The temperature of the solution is 80°C. The processing time depends on the intensity of the color.
Compositions of solutions for oxidation and coloring of copper (g/l)
bluish black colors
Caustic soda - 600 ... 650, sodium nitrate - 100 ... 200. Solution temperature - 140°C, processing time - 2 hours.
Caustic soda - 550, sodium nitrite - 150 ... 200. Solution temperature - 135...140°С, processing time - 15...40 min.
Caustic soda - 700...800, sodium nitrate - 200...250, sodium nitrite -50...70. Solution temperature - 140...150°С, processing time - 15...60 min.
Caustic soda - 50 ... 60, potassium persulfate - 14 ... 16. Solution temperature - 60...65 C, processing time - 5...8 min.
Potassium sulfide - 150. Solution temperature - 30°C, processing time - 5...7 min.
In addition to the above, a solution of the so-called sulfuric liver is used. Sulfur liver is obtained by fusing in an iron can for 10 ... 15 minutes (with stirring) 1 part (by weight) of sulfur with 2 parts of potassium carbonate (potash). The latter can be replaced by the same amount of sodium carbonate or caustic soda.
The glassy mass of sulfuric liver is poured onto an iron sheet, cooled and crushed to a powder. Store sulfur liver in an airtight container.
A solution of sulfuric liver is prepared in an enamel bowl at the rate of 30...150 g/l, the temperature of the solution is 25...100°C, the processing time is determined visually.
With a solution of sulfuric liver, in addition to copper, silver can be well blackened and steel satisfactorily.
Green color
Copper nitrate - 200, ammonia (25% solution) - 300, ammonium chloride - 400, sodium acetate - 400. Solution temperature - 15...25°C. The color intensity is determined visually.
Brown color
Potassium chloride - 45, nickel sulphate - 20, copper sulphate - 100. Solution temperature - 90...100°C, color intensity is determined visually.
Brownish yellow color
Caustic soda - 50, potassium persulfate - 8. Solution temperature - 100°C, processing time - 5...20 min.
Blue
Sodium thiosulfate - 160, lead acetate - 40. Solution temperature - 40 ... 100 ° C, processing time - up to 10 minutes.
Compositions for oxidation and coloring of brass (g/l)
Black color
Copper carbonate - 200, ammonia (25% solution) - 100. Solution temperature - 30 ... 40 ° C, processing time - 2 ... 5 minutes.
Copper bicarbonate - 60, ammonia (25% solution) - 500, brass (sawdust) - 0.5. Solution temperature - 60...80°С, processing time - up to 30 min.
Brown color
Potassium chloride - 45, nickel sulfate - 20, copper sulfate - 105. Solution temperature - 90 ... 100 ° C, processing time - up to 10 minutes.
Copper sulphate - 50, sodium thiosulfate - 50. Solution temperature - 60 ... 80 ° C, processing time - up to 20 minutes.
Sodium sulfate - 100. Solution temperature - 70°C, processing time - up to 20 minutes.
Copper sulphate - 50, potassium permanganate - 5. Solution temperature - 18 ... 25 ° C, processing time - up to 60 minutes.
Blue
Lead acetate - 20, sodium thiosulfate - 60, acetic acid (essence) - 30. Solution temperature - 80 ° C, processing time - 7 minutes.
3 green color
Nickel ammonium sulphate - 60, sodium thiosulfate - 60. Solution temperature - 70 ... 75 ° C, processing time - up to 20 minutes.
Copper nitrate - 200, ammonia (25% solution) - 300, ammonium chloride - 400, sodium acetate - 400. Solution temperature - 20 ° C, processing time - up to 60 minutes.
Compositions for oxidation and coloring of bronze (g/l)
Green color
Ammonium chloride - 30, 5% acetic acid - 15, medium acetic copper salt - 5. Solution temperature - 25...40°C. Hereinafter, the color intensity of bronze is determined visually.
Ammonium chloride - 16, acidic potassium oxalate - 4, 5% acetic acid - 1. Solution temperature - 25...60°C.
Copper nitrate - 10, ammonium chloride - 10, zinc chloride - 10. Solution temperature - 18...25°C.
yellow- green color
Nitrate copper - 200, sodium chloride - 20. Solution temperature - 25°C.
Blue to yellow-green
Depending on the processing time, it is possible to obtain colors from blue to yellow-green in a solution containing ammonium carbonate - 250, ammonium chloride - 250. Solution temperature - 18...25°C.
Patination (giving the appearance of old bronze) is carried out in the following solution: sulfuric liver - 25, ammonia (25% solution) - 10. Solution temperature - 18 ... 25 ° C.
Compositions for oxidation and coloring of silver (g/l)
Black color
Sulfuric liver - 20...80. Solution temperature - 60..70°С. Hereinafter, the color intensity is determined visually.
Ammonium carbonate - 10, potassium sulfide - 25. Solution temperature - 40...60°C.
Potassium sulphate - 10. Solution temperature - 60°C.
Copper sulphate - 2, ammonium nitrate - 1, ammonia (5% solution) - 2, acetic acid (essence) - 10. Solution temperature - 25...40°C. The content of the components in this solution is given in parts (by weight).
Brown color
A solution of ammonium sulphate - 20 g / l. Solution temperature - 60...80°C.
Copper sulphate - 10, ammonia (5% solution) - 5, acetic acid - 100. Solution temperature - 30...60°C. The content of the components in the solution - in parts (by weight).
Copper sulphate - 100, 5% acetic acid - 100, ammonium chloride - 5. Solution temperature - 40...60°C. The content of the components in the solution - in parts (by weight).
Copper sulphate - 20, potassium nitrate - 10, ammonium chloride - 20, 5% acetic acid - 100. Solution temperature - 25...40°C. The content of the components in the solution - in parts (by weight).
Blue
Sulfuric liver - 1.5, ammonium carbonate - 10. Solution temperature - 60°C.
Sulfuric liver - 15, ammonium chloride - 40. Solution temperature - 40...60°C.
Green color
Iodine - 100, hydrochloric acid - 300. Solution temperature - 20°C.
Iodine - 11.5, potassium iodide - 11.5. The temperature of the solution is 20°C.
Attention! When dyeing silver green, you must work in the dark!
Composition for oxidation and coloring of nickel (g/l)
Nickel can only be painted black. The solution (g/l) contains: ammonium persulfate - 200, sodium sulfate - 100, iron sulfate - 9, ammonium thiocyanate - 6. Solution temperature - 20...25°C, processing time - 1-2 minutes.
Compositions for the oxidation of aluminum and its alloys (g/l)
Black color
Ammonium molybdate - 10...20, ammonium chloride - 5...15. Solution temperature - 90...100°С, treatment time - 2...10 min.
Grey colour
Arsenic trioxide - 70...75, sodium carbonate - 70...75. Solution temperature - boiling, processing time - 1...2 min.
Green color
Orthophosphoric acid - 40 ... 50, acidic potassium fluoride - 3 ... 5, chromic anhydride - 5 ... 7. Solution temperature - 20...40 C, processing time - 5...7 min.
Orange color
Chromic anhydride - 3...5, sodium fluorine silicate - 3...5. Solution temperature - 20...40°С, processing time - 8...10 min.
tan color
Sodium carbonate - 40 ... 50, sodium chlorate - 10 ... 15, caustic soda - 2 ... 2.5. Solution temperature - 80...100°С, processing time - 3...20 min.
Protective compounds
Often, the craftsman needs to process (paint, cover with another metal, etc.) only part of the craft, and leave the rest of the surface unchanged.
To do this, the surface that does not need to be covered is painted over with a protective compound that prevents the formation of a particular film.
The most affordable, but not heat-resistant protective coatings- waxy substances (wax, stearin, paraffin, ceresin) dissolved in turpentine. To prepare such a coating, wax and turpentine are usually mixed in a ratio of 2: 9 (by weight). Prepare this composition as follows. Wax is melted in a water bath and warm turpentine is introduced into it. To protective compound would be contrast (its presence could be clearly seen, controlled), a small amount of dark-colored paint soluble in alcohol is introduced into the composition. If this is not available, it is easy to introduce a small amount of dark shoe cream into the composition.
You can give a recipe that is more complex in composition,% (by weight): paraffin - 70, beeswax - 10, rosin - 10, pitch varnish (Kuzbasslak) - 10. All components are mixed, melted over low heat and mixed thoroughly.
Wax-like protective compounds are applied hot with a brush or swab. All of them are designed for operating temperatures up to 70°C.
Somewhat better heat resistance (operating temperature up to 85°С) is possessed by protective compositions based on asphalt, bituminous and pitch varnishes. Usually they are thinned with turpentine in a ratio of 1:1 (by weight). The cold composition is applied to the surface of the part with a brush or swab. Drying time - 12...16 hours.
Perchlorovinyl paints, varnishes and enamels withstand temperatures up to 95°C, oil-bitumen varnishes and enamels, asphalt-oil and bakelite varnishes - up to 120°C.
The most acid-resistant protective composition is a mixture of 88N glue (or Moment) and filler (porcelain flour, talc, kaolin, chromium oxide), taken in the ratio: 1:1 (by weight). The required viscosity is obtained by adding to the mixture a solvent consisting of 2 parts (by volume) of B-70 gasoline and 1 part of ethyl acetate (or butyl acetate). The working temperature of such a protective composition is up to 150 C.
A good protective composition is epoxy varnish (or putty). Operating temperature - up to 160°С.
Nickel-plated coatings have a number of valuable properties: they are well polished, acquiring a beautiful long-lasting mirror finish, they are durable and well protect the metal from corrosion.
The color of nickel plating is silvery white with a yellowish tint; they are easily polished, but fade over time. The coatings are characterized by a fine-grained structure, good adhesion to steel and copper substrates, and the ability to passivate in air.
Nickel plating is widely used as a decorative coating for parts of lamps intended for lighting public and residential premises.
To cover steel products, nickel plating is often carried out over an intermediate copper sublayer. Sometimes a three-layer nickel-copper-nickel coating is used. In some cases, a thin layer of chromium is applied to the nickel layer, and a nickel-chromium coating is formed. On parts made of copper and alloys based on it, nickel is applied without an intermediate sublayer. The total thickness of two and three-layer coatings is regulated by mechanical engineering standards, usually it is 25–30 microns.
On parts intended for operation in a humid tropical climate, the coating thickness should be at least 45 microns. In this case, the regulated thickness of the nickel layer is not less than 12–25 µm.
To obtain brilliant coatings, nickel-plated parts are polished. Recently, brilliant nickel plating has been widely used, which eliminates the laborious operation of mechanical polishing. Brilliant nickel plating is achieved by introducing brighteners into the electrolyte. However, the decorative qualities of mechanically polished surfaces are higher than those obtained by bright nickel plating.
Nickel deposition occurs with significant cathodic polarization, which depends on the temperature of the electrolyte, its concentration, composition, and some other factors.
Electrolytes for nickel plating are relatively simple in composition. Currently, sulfate, hydroboric fluoride and sulfamic electrolytes are used. Lighting factories use exclusively sulfate electrolytes, which allow them to work with high current densities and at the same time obtain high-quality coatings. The composition of these electrolytes includes salts containing nickel, buffer compounds, stabilizers and salts that contribute to the dissolution of the anodes.
The advantages of these electrolytes are the lack of components, high stability and low aggressiveness. Electrolytes allow a high concentration of nickel salt in their composition, which makes it possible to increase the cathode current density and, consequently, to increase the productivity of the process.
Sulfate electrolytes have high electrical conductivity and good dissipation ability.
An electrolyte of the following composition, g/l, has been widely used:
NiSO4 7H2O
240–250
*Or NiCl2 6H2O - 45 g/l.
Nickel plating is carried out at a temperature of 60°C, pH=5.6÷6.2 and a cathodic current density of 3–4 A/dm2.
Depending on the composition of the bath and its mode of operation, coatings with varying degrees of gloss can be obtained. For these purposes, several electrolytes have been developed, the compositions of which are given below, g/l:
for matte finish:
NiSO4 7H2O
180–200
Na2SO4 10H2O
80–100
H3BO3
30–35
Nickel plated at a temperature of 25–30°C, at a cathodic current density of 0.5–1.0 A/dm2 and pH=5.0÷5.5;
for a semi-gloss finish:
Nickel sulfate NiSO4 7H2O 200–300
Boric acid H3BO3 30
2,6–2,7-Disulfonaphthalic acid 5
Sodium fluoride NaF 5
Sodium chloride NaCl 7–10
Nickel plating is carried out at a temperature of 20–35°C, cathodic current density 1–2 A/dm2 and pH=5.5÷5.8;
for a shiny finish:
Nickel sulfate (hydrate) 260–300
Nickel chloride (hydrate) 40–60
Boric acid 30–35
Saccharin 0.8–1.5
1,4-butyndiol (in terms of 100%) 0.12-0.15
Phthalimide
0,08–0,1
Nickel plating operating temperature 50–60°C, electrolyte pH 3.5–5, cathodic current density with intensive stirring and continuous filtration 2–12 A/dm2, anode current density 1–2 A/dm2.
A feature of nickel plating is a narrow range of electrolyte acidity, current density and temperature.
To maintain the composition of the electrolyte within the required limits, buffer compounds are introduced into it, which are most often used as boric acid or a mixture boric acid with sodium fluoride. In some electrolytes, citric, tartaric, acetic acid or their alkaline salts.
A feature of nickel coatings is their porosity. In some cases, dotted spots, the so-called "pitting", may appear on the surface.
To prevent pitting, intensive air mixing of the baths and shaking of the suspensions with parts attached to them are used. The reduction of pitting is facilitated by the introduction of surface tension reducers or wetting agents into the electrolyte, which are used as sodium lauryl sulfate, sodium alkyl sulfate and other sulfates.
The domestic industry produces a good anti-pitting detergent"Progress", which is added to the bath in the amount of 0.5 mg / l.
Nickel plating is very sensitive to impurities that enter the solution from the surface of parts or due to anodic dissolution. When nickel plating steel de-
hoists, the solution is clogged with iron impurities, and when coating copper-based alloys - with its impurities. Impurities are removed by alkalizing the solution with carbonate or nickel hydroxide.
Organic pitting contaminants are removed by boiling the solution. Sometimes nickel-plated parts are tinted. In this case, colored surfaces with a metallic sheen are obtained.
Toning is carried out by a chemical or electrochemical method. Its essence lies in the formation of a thin film on the surface of the nickel coating, in which light interference occurs. Such films are obtained by applying organic coatings several micrometers thick to nickel-plated surfaces, for which the parts are treated in special solutions.
Black nickel coatings have good decorative qualities. These coatings are obtained in electrolytes in which zinc sulfates are added in addition to nickel sulfates.
The composition of the electrolyte for black nickel plating is as follows, g/l:
Nickel sulfate 40–50
Zinc sulfate 20-30
Potassium thiocyanate 25–32
Ammonium sulphate 12–15
Nickel plating is carried out at a temperature of 18–35°C, cathodic current density of 0.1 A/dm2 and pH=5.0÷5.5.
2. CHROME PLATE
Chrome coatings have high hardness and wear resistance, low coefficient of friction, are resistant to mercury, adhere strongly to the base metal, and are chemically and heat resistant.
In the manufacture of lamps, chromium plating is used to obtain protective and decorative coatings, as well as reflective coatings in the manufacture of mirror reflectors.
Chrome plating is carried out on a pre-applied copper-nickel or nickel-copper-nickel sublayer. The thickness of the chromium layer with such a coating usually does not exceed 1 μm. In the manufacture of reflectors, chromium plating is currently being replaced by other coating methods, but in some factories it is still used for the manufacture of reflectors for mirrored lamps.
Chromium has good adhesion to nickel, copper, brass and other materials to be deposited, however, when other metals are deposited onto chromium, poor adhesion is always observed.
A positive feature of chromium coatings is that the parts are shiny directly in galvanic baths, this does not require them to be polished mechanically. Along with this, chromium plating differs from other galvanic processes by more stringent requirements for the operating mode of the baths. Minor deviations from the required current density, electrolyte temperature and other parameters inevitably lead to deterioration of coatings and mass rejects.
The scattering power of chromium electrolytes is low, resulting in poor coverage. internal surfaces and recessed parts. To improve the uniformity of coatings, special suspensions and additional screens are used.
For chromium plating, solutions of chromic anhydride with the addition of sulfuric acid are used.
Three types of electrolytes have found industrial application: diluted, universal and concentrated (Table 1). For getting decorative coatings and concentrated electrolyte is used to obtain reflectors. In chromium plating, insoluble lead anodes are used.
Table 1 - Electrolyte compositions for chromium plating
During operation, the concentration of chromic anhydride in the baths decreases, therefore, to restore the baths, daily adjustments are made by adding fresh chromic anhydride to them.
Several formulations of self-regulating electrolytes have been developed, in which the concentration ratio is automatically stored.
The composition of such an electrolyte is as follows, g/l:
Chrome plating is carried out at a cathode current density of 50–80 A/dm2 and a temperature of 60–70°C.
Depending on the relationship between temperature and current density, different types of chromium coating can be obtained: milky shiny and matte.
The milky coating is obtained at a temperature of 65–80 ° C and
low current density. A brilliant coating is obtained at a temperature of 45–60°C and an average current density. Matte finish obtained at a temperature of 25–45°C and a high current density. In the production of fixtures, a shiny chrome coating is most often used.
To obtain mirror reflectors, chromium plating is carried out at a temperature of 50–55°C and a current density of 60 A/dm2. in the manufacture of mirror reflectors, copper and nickel are pre-deposited. The reflective surface is polished after applying each of the layers. The technological process includes the following operations:
grinding and polishing the surface;
copper plating;
nickel plating;
polishing, degreasing, pickling;
chrome plating;
clean polishing.
After each technological operation, a 100% quality control of the coating is carried out, since non-compliance with the requirements of the technology leads to peeling of the sublayer along with the chromium coating.
Products made of copper and copper alloys are chromium-plated without an intermediate sublayer. The parts are immersed in the electrolyte after voltage is applied to the bath. When applying multilayer coatings to steel products, the layer thickness is regulated by GOST 3002-70. Thickness values are given in table 2.
Table 2 - Minimum thickness of multilayer galvanized coatings
Chrome plating baths are equipped with powerful exhaust ventilation to remove poisonous chromic acid vapors.
During chromium plating, part of the hexavalent chromium Cr6+ gets into wastewater, therefore, to prevent Cr6+ emissions into open water, protective measures are used - neutralizers and treatment facilities are installed.
1. Afanas'eva E.I., Skobelev V.M. "Light sources and ballasts: Textbook for technical schools", 2nd ed., Rev., M: Energoatomizdat, 1986, 270s.
2. Bolenok V.E. "Production of electric lighting devices: Textbook for technical schools", M: Energoizdat, 1981, 303s.
3. Denisov V.P. "Production of electric light sources", M: Energy, 1975, 488s.
4. Denisov V.P., Melnikov Yu.F. "Technology and equipment for the production of electric light sources: Textbook for technical schools", M: Energy, 1983, 384s.
5. Plyaskin P.V. etc. "Fundamentals of designing electrical light sources", M: Energoatomizdat, 1983, 360s.
6. Churkina N.I., Lityushkin V.V., Sivko A.P. "Fundamentals of technology of electric light sources" / ed. ed. Prytkova A.A., Saransk: Mordovian book publishing house, 2003, 344p.
The presented training courses are to help beginners who love decorative chrome plating of chemical plating. The purpose of the training courses is to fill the gap of systematized knowledge on the topic of decorative chrome plating by chemical plating and make this technology more accessible to beginners. The submitted texts, photos and videos are personal experience the author, who does not claim to be professional. The author of the training courses is not responsible for possible injuries, burns and poisoning associated with the use of hazardous chemicals such as concentrated acids, alkalis, ammonia. Therefore, do not neglect protective equipment and care when handling reagents.
Decorative chrome plating, chemical plating, all these terms and processes were not known to me not so long ago. Dear friend, since you are on this site, it means that you are also hooked on this topic and you are looking for answers to questions. Questions that haunt you ... How to make any thing with a mirror shine? However, the answers are very close, just sit back and carefully look at the contents of this page. In fact, this is a technology of mirror silvering by spraying. This is also called chemical silver plating. So, there is no talk of real chrome plating, but the name has taken root and is misleading. When I started collecting information on this topic, I was faced with the fact that there is a lot of information on the topic of decorative chrome plating, but to my amazement, nothing specific. All around, yes. Here are a lot of videos where garage craftsmen, as well as pros selling equipment, are happy to demonstrate the process of transforming a nondescript detail into a product sparkling with a mirror. But step by step all the technology, no one lays out for nothing, inflating a big one out of it, a big secret... There are many questions, but the answers are paid ...
After reading a mountain of sites and textbooks, a mess formed in my head, probably, like many others, faced with such a task. So that a clear picture appeared in my head, I decided to immediately practice. It is clear that without chemistry, you will not learn how to chemistry, so I began to search and bypass the offices that sell chemistry. First of all, I asked the price for silver nitrate, since this is the most expensive component. Decide on a supplier. For bought on the list of chemicals, dishes and other necessary utensils. The question arose how to try without equipment. The solution is simple - manual household sprayers. The search and experiments began to create a miracle solution of silvering and application technology. And then one interesting detail about the preparation of chemistry emerged ... All the available information posted on the Internet is a copy of the materials of mainly Soviet textbooks on the topic of chemical metallization ...
Draining a fair amount of silver (respectively, money) to the ground in the process of unsuccessful experiments. Came for a pretty good recipe. In other words, everything is in order. This is the end of the lyrical introduction and the beginning of a short course on how to make a thing a mirror. I will not ship the theory, I will leave it for self-study. There is a lot of this goodness on the Internet. Let's get straight to the point. Short, concise, to the point. I will show you on the example of silvering a glass cup.
Technology of chemical metallization with silver, sputtering method
To get the first experience of silver coating on the surface, by spraying, you should learn the technology. And to put it simply - the sequence of actions.
I will list them:
1. preparation of solutions
2. surface preparation
3.surface activation
4. plating
ladies short review listed items. To get the big picture in my head. Let's take a closer look at the lessons of the same name.
Preparation of solutions
To prepare solutions you will need:
- stannous chloride
- Hydrochloric acid
- Nitrate silver
- Sodium hydroxide
- Ammonia
- Glucose
- Formalin
- Distilled water
From the equipment you will need:
- Measuring cup for 1 liter
- Measuring cup for 200 - 250 ml.
- 100 ml bottles - 3 pcs.
- Disposable syringes for 5, 20 and 50 cubes
- Disposable cups per 50 ml
- Disposable knives and spoons
- Electronic scales, measuring up to 200 gr.
You can start preparing solutions with a solution of tin dichloride. Required to activate the surface. For this we take:
1. Stannous chloride
2. Hydrochloric acid
3. Distilled water
The next solution is "silver". We take:
1. Nitrate silver
2. Sodium hydroxide
3. Ammonia
4. Distilled water
Surface preparation
To prepare the surface, it must be degreased. To do this, you can prepare a simple degreasing solution, consisting of:
1. Sodium hydroxide
2. and water temperature 40-60 degrees
The surface should be carefully wiped with a sponge moistened with a degreasing solution. Then wash off the solution with distilled water, wiping, but with another sponge. A sign of good degreasing is the wettability of the surface with water. That is, watering with water, the entire surface should be covered with a water film. If there are dry islands, silver will not stick there.
Surface activation
In order for the metallization reaction to take place precisely on the surface, and not in the sink, it is necessary to activate it, as they say. That is, to help the silver stick to the surface. It is for this that we take a solution of tin dichloride. It's very important point procedure time. Water the part with a solution of stannous chloride for one minute. Then pour with distilled water - three minutes. This is very milestone and non-observance of the surface treatment time leads to marriage, that is, to a waste of time, effort and money. Watering should be as even as possible so that all areas of the surface are equally moistened.
Metallization
This is the most interesting stage of obtaining a mirror film of silver on the surface. Actually for the sake of this, the whole idea. To do this, you need only a silver solution and a reducing agent solution. This will require some skill, which comes with experience. It is necessary to spray so that the solutions mix on the surface and nothing else. And sprayed in equal amounts by volume. Having reached such accuracy, we get an ideal mirror, without defects.
In addition, you should know that the resulting mirror film is not durable and in order for it to retain its properties, it should be protected with a layer of transparent or tinted varnish. But that's a completely different story.
The process of decorative chrome plating can be repeated even at home in the bathroom without buying expensive equipment with minimal cost. You can get acquainted with the technology in more detail by studying the email course Technology of decorative chrome plating and trying it in practice, it will allow you to decide whether it is worth moving further in this direction.
What does the email course "Technology of decorative chrome plating" consist of?
- Chemistry and equipment.
- Recipes and preparation of solutions for silvering.
- Surface preparation for silver application.
- Metallization
Nickel-plated coatings have a number of valuable properties: they are well polished, acquiring a beautiful long-lasting mirror finish, they are durable and well protect the metal from corrosion.
The color of nickel plating is silvery white with a yellowish tint; they are easily polished, but fade over time. The coatings are characterized by a fine-grained structure, good adhesion to steel and copper substrates, and the ability to passivate in air.
Nickel plating is widely used as a decorative coating for parts of lamps intended for lighting public and residential premises.
To cover steel products, nickel plating is often carried out over an intermediate copper sublayer. Sometimes a three-layer nickel-copper-nickel coating is used. In some cases, a thin layer of chromium is applied to the nickel layer, and a nickel-chromium coating is formed. On parts made of copper and alloys based on it, nickel is applied without an intermediate sublayer. The total thickness of two and three-layer coatings is regulated by mechanical engineering standards, usually it is 25–30 microns.
On parts intended for operation in a humid tropical climate, the coating thickness should be at least 45 microns. In this case, the regulated thickness of the nickel layer is not less than 12–25 µm.
To obtain brilliant coatings, nickel-plated parts are polished. Recently, brilliant nickel plating has been widely used, which eliminates the laborious operation of mechanical polishing. Brilliant nickel plating is achieved by introducing brighteners into the electrolyte. However, the decorative qualities of mechanically polished surfaces are higher than those obtained by bright nickel plating.
Nickel deposition occurs with significant cathodic polarization, which depends on the temperature of the electrolyte, its concentration, composition, and some other factors.
Electrolytes for nickel plating are relatively simple in composition. Currently, sulfate, hydroboric fluoride and sulfamic electrolytes are used. Lighting factories use exclusively sulfate electrolytes, which allow them to work with high current densities and at the same time obtain high-quality coatings. The composition of these electrolytes includes salts containing nickel, buffer compounds, stabilizers and salts that contribute to the dissolution of the anodes.
The advantages of these electrolytes are the lack of components, high stability and low aggressiveness. Electrolytes allow a high concentration of nickel salt in their composition, which makes it possible to increase the cathode current density and, consequently, to increase the productivity of the process.
Sulfate electrolytes have high electrical conductivity and good dissipation ability.
An electrolyte of the following composition, g/l, has been widely used:
NiSO4 7H2O240–250
*Or NiCl2 6H2O - 45 g/l.
Nickel plating is carried out at a temperature of 60°C, pH=5.6÷6.2 and a cathodic current density of 3–4 A/dm2.
Depending on the composition of the bath and its mode of operation, coatings with varying degrees of gloss can be obtained. For these purposes, several electrolytes have been developed, the compositions of which are given below, g/l:
for matte finish:
NiSO4 7H2O180–200
Na2SO4 10H2O80–100
Nickel plated at a temperature of 25–30°C, at a cathodic current density of 0.5–1.0 A/dm2 and pH=5.0÷5.5;
for a semi-gloss finish:
Nickel sulfate NiSO4 7H2O200–300
Boric acid H3BO330
2,6–2,7-Disulfonaphthalic acid5
Sodium fluoride NaF5
Sodium chloride NaCl7–10
Nickel plating is carried out at a temperature of 20–35°C, cathodic current density 1–2 A/dm2 and pH=5.5÷5.8;
for a shiny finish:
Nickel sulfate (hydrate) 260–300
Nickel chloride (hydrate) 40–60
Boric acid30–35
Saccharin0.8–1.5
1,4-butyndiol (in terms of 100%) 0.12-0.15
Phthalimide 0.08–0.1
Nickel plating operating temperature 50–60°C, electrolyte pH 3.5–5, cathodic current density with intensive stirring and continuous filtration 2–12 A/dm2, anode current density 1–2 A/dm2.
A feature of nickel plating is a narrow range of electrolyte acidity, current density and temperature.
To maintain the composition of the electrolyte within the required limits, buffer compounds are introduced into it, which are most often used as boric acid or a mixture of boric acid with sodium fluoride. In some electrolytes, citric, tartaric, acetic acid or their alkaline salts are used as buffer compounds.
A feature of nickel coatings is their porosity. In some cases, dotted spots, the so-called "pitting", may appear on the surface.
To prevent pitting, intensive air mixing of the baths and shaking of the suspensions with parts attached to them are used. The reduction of pitting is facilitated by the introduction of surface tension reducers or wetting agents into the electrolyte, which are used as sodium lauryl sulfate, sodium alkyl sulfate and other sulfates.
The domestic industry produces a good anti-pitting detergent "Progress", which is added to the bath in an amount of 0.5 mg / l.
Nickel plating is very sensitive to impurities that enter the solution from the surface of parts or due to anodic dissolution. When nickel plating steel de-
hoists, the solution is clogged with iron impurities, and when coating copper-based alloys - with its impurities. Impurities are removed by alkalizing the solution with carbonate or nickel hydroxide.
Organic pitting contaminants are removed by boiling the solution. Sometimes nickel-plated parts are tinted. In this case, colored surfaces with a metallic sheen are obtained.
Toning is carried out by a chemical or electrochemical method. Its essence lies in the formation of a thin film on the surface of the nickel coating, in which light interference occurs. Such films are obtained by applying organic coatings several micrometers thick to nickel-plated surfaces, for which the parts are treated in special solutions.
Black nickel coatings have good decorative qualities. These coatings are obtained in electrolytes in which zinc sulfates are added in addition to nickel sulfates.
The composition of the electrolyte for black nickel plating is as follows, g/l:
Nickel sulfate40–50
Zinc sulfate20–30
Potassium thiocyanate25–32
Ammonium sulphate12–15
Nickel plating is carried out at a temperature of 18–35°C, cathodic current density of 0.1 A/dm2 and pH=5.0÷5.5.
2. CHROME PLATE
Chrome coatings have high hardness and wear resistance, low coefficient of friction, are resistant to mercury, adhere strongly to the base metal, and are chemically and heat resistant.
In the manufacture of lamps, chromium plating is used to obtain protective and decorative coatings, as well as reflective coatings in the manufacture of mirror reflectors.
Chrome plating is carried out on a pre-applied copper-nickel or nickel-copper-nickel sublayer. The thickness of the chromium layer with such a coating usually does not exceed 1 μm. In the manufacture of reflectors, chromium plating is currently being replaced by other coating methods, but in some factories it is still used for the manufacture of reflectors for mirrored lamps.
Chromium has good adhesion to nickel, copper, brass and other materials to be deposited, however, when other metals are deposited onto chromium, poor adhesion is always observed.
A positive feature of chromium coatings is that the parts are shiny directly in galvanic baths, this does not require them to be polished mechanically. Along with this, chromium plating differs from other galvanic processes by more stringent requirements for the operating mode of the baths. Minor deviations from the required current density, electrolyte temperature and other parameters inevitably lead to deterioration of coatings and mass rejects.
The scattering power of chromium electrolytes is low, which leads to poor coating of internal surfaces and recesses of parts. To improve the uniformity of coatings, special suspensions and additional screens are used.
For chromium plating, solutions of chromic anhydride with the addition of sulfuric acid are used.
Three types of electrolytes have found industrial application: diluted, universal and concentrated (Table 1). To obtain decorative coatings and to obtain reflectors, a concentrated electrolyte is used. In chromium plating, insoluble lead anodes are used.
Table 1 - Electrolyte compositions for chromium plating
During operation, the concentration of chromic anhydride in the baths decreases, therefore, to restore the baths, daily adjustments are made by adding fresh chromic anhydride to them.
Several formulations of self-regulating electrolytes have been developed, in which the concentration ratio is automatically stored
.The composition of such an electrolyte is as follows, g/l:
Chrome plating is carried out at a cathode current density of 50–80 A/dm2 and a temperature of 60–70°C.
Depending on the relationship between temperature and current density, different types of chromium coating can be obtained: milky shiny and matte.
Chrome/Nickel
(too old post to reply)
2005-03-27 19:01:08 UTC
Nickel plating?
I know that both are used to coat metal surfaces in order to
make them shiny and protect against corrosion.
Cost difference?
Oleg ICQ#168343240
Who gets up early - he gets everyone
Leizer A. Karabin
2005-03-28 04:58:10 UTC
Good afternoon, Oleg light Antoshkiv!
I actually just came out Monday March 28 2005 00:01,
here I hear - Oleg Antoshkiv says All (well, I butted in, of course):
OA> The question is purely out of curiosity: what is the difference between chrome plating and
OA> nickel plating?
I hope this question is rhetorical. Or explain.
OA> I know that both are used to coat metal
OA> surfaces to make them shiny and protect against corrosion.
OA> How to distinguish a chrome-plated surface from a nickel-plated one by eye?
Nickel is slightly yellowish, chrome is slightly bluer.
OA> What is the difference in mechanical strength, chemical resistance?
For improvised and home chemistry, both are absolutely resistant.
OA> The difference in cost?
Chrome plating is definitely more expensive.
OA> Is the coating technology the same?
Very different. For example, traditional bumper chrome plating technology
it's nickel - copper - nickel - glitter. nickel - chromium on steel. or without first
nickel sublayer, if you get permission for copper from a cyanide al-ta.
If it seemed to you that there are just single-layer
decorative anti-corrosion coatings, then only Chinese-underground watches.
Half a micron of chrome or gold on bronze is enough for a couple of weeks of wearing.
OA> Is there any difference what metals can be coated with both?
The difference is in technology, but in general, any can be covered with anything.
Why do you need to find out what is where, or did you gather yourself? The last "M-nee, no
I advise, they will eat it!" (C)
For sim forever and so on. Leizer (ICQ 62084744)
2005-03-28 08:07:29 UTC
Greetings, Oleg!
Monday March 28 2005 00:01, Oleg Antoshkiv -> All:
OA> The question is purely out of curiosity: what is the difference between chrome plating and
OA> nickel plating?
different metals
OA> I know that both are used to cover
OA>
OA> corrosion. How to distinguish a chrome surface by eye
OA> nickel-plated?
Nickel is usually just white and chrome plating can change color though
usually slightly purple.
OA> What is the difference in mechanical strength, chemical resistance?
Chrome plating gives a harder coating than nickel, chemically chromium
continues to protect the base metal (if it is steel) with minor damage
coating, in the case of nickel, corrosion only accelerates if the coating is damaged.
OA> The difference in cost?
who knows
OA> Is the coating technology the same?
At least on steel products, chromium is deposited directly, and nickel
through the substrate (copper).
OA> Is there any difference what metals can be coated with both?
Sincerely, Sergey Din.
Andrew Mitrohin
2005-03-28 13:26:07 UTC
*_Be healthy_*, /_Oleg_/!
OA> The question is purely out of curiosity: what is the difference between chrome plating and
OA> nickel plating? I know that both are used to cover
OA> metal surfaces to make them shiny and protect from
OA> corrosion.
OA> How to distinguish a chrome-plated surface from a nickel-plated one by eye
OA>?
The color is different.
OA> What is the difference in mechanical strength, chemical resistance?
Chrome is better in this regard.
OA> The difference in cost?
Before nickel plating, the metal is coated with copper and polished.
Before plating with chromium - the metal is first coated with copper, then with nickel and
then chrome. Then the cover is strong.
OA> Is the coating technology the same?
Different, it’s better to forget about chrome at home. Chromic anhydride is used
which is very toxic.
OA> Is there any difference what metals can be coated with both?
It all depends, if I'm not mistaken, on the activity of the metal.
/With respect/, _/Andrew/_...
- [Russian rock music] -
