DE1521447B2 - PROCESS FOR DIFFUSION COATING OF METAL PRODUCTS - Google Patents

Description

I 521 447

1 2

The invention relates to a method for diffusing quenching baths located below about 300 ° C.

sion coating of metal products with a dip.

Calcium, Strontium, Barium, Magnesium or The liquid sodium frightens the coated

Lithium as a metal transfer agent and minor product is rapidly declining. Surprisingly, it stays that way

at least one diffusing metallic element is formed 5 resistant to sodium, and there is hardly any reaction

holding melt. tion with the excess adhering to the product

The Germans. Patents 1253 989, 1259 669 and. transport medium and hardly any evaporation of the 1292464 concern diffusion coating processes. metallic sodium instead, although this would have to be expected in the case of those in which metal products on the surface at higher temperatures at which the are coated by being immersed in a molten bath ίο teten products, would have a transfer medium and a can. It is surprising that sodium oxide and or more diffusing metallic elements ■ Sodium hydroxide, which is always on the surface of. In these processes, the molten sodium to be coated will float if the product to be coated has not been immersed in a molten metal under extreme precaution for a certain period of time, then treated from the bath to exclude air, excepted, cooled and cleaned . One does not get violently reacting with the transfer medium, thereby coatings with exceptionally good properties. It is often advisable to clean the coated transfer media, if they are to cool metal products quickly or to repel them - practically free of tarnish marks,
ken. This is particularly true when one uses the chromium-containing coating process when carrying out the unstabilized iron products according to the invention. Such products must contain elements that have to be quenched to the desired working temperature in order to allow the migration of coherence. This temperature is between about carbon to the surface of the product and thus 25 900 ° C and the melting point of the to be coated a reduction in the corrosion resistance of the product. A second bath to prevent the liquid. Contains sodium, is preferably

The previous quenching processes have kept the temperature between 100 and 300 ° C; man have not proven to be completely satisfactory, but higher temperatures can also be used, the products when they are from the molten 30 The metal product to be coated is for a Coating bath to be taken out, over-certain period of time in the melted transfers submerged from the molten transfer agent, the diffusing that adhere to their surface. The at. Element is alloyed with the base metal. Think about that Diffusion coating process applied layered metal product is then transferred from the loading medium but react violently with water when the coating bath is removed and quickly in the frightening temperatures. In addition, quenching bath transferred. The transfer time exists when water is used as a quenchant in such a way that the product is at a temperature a tendency of the surfaces to tarnish at a temperature above the boiling point of sodium, receive. You also already have oils as a quenching agent until it is immersed in the quenching bath. the medium used; but these decompose easily at 4 ° most favorable temperatures and periods for the the higher temperatures. In addition, transfer to the quench bath also tend to depend on the oils used to discolor the metal surfaces, and factors such as the relative size (mass) of the Ersie cause a strong carburization of the coating, certificate and the amount of material of the quenching the corrosion resistance affects the bath. Preferably the transfer time is not will. It has also been found that quenchants, 45 longer than about 60 seconds; Transfer times the carbon compounds or volatile carbons of about 10 to 30 seconds are preferred. the Containing hydrogens add considerably to carbon- the amount of quenchant in the bath is said to be content of the coatings contribute. Strong gas flows are sufficient to apply the coated product to a and fluidized beds have proven to be of limited effect- temperature to cool below about 350 ° C before They have been proven and require, if one considers an out- 50 an appreciable migration of undesirable wants to achieve sufficient cooling speed, the elements, such as carbon, in the coated Use of expensive and cumbersome equipment has taken place. The deterrent duration In addition, quenching according to the should generally requires in the range of about 1 to 3 Se fluidized bed processes the circulation and the return. announce lie.

extraction of large quantities of inert gases, 55 As stated in patent specification 1292 464,

if the tarnishing of the metals is avoided, they remove transmission media, especially calcium,

target. the alloyed part of the coated product

The invention relates to a method for carbon. By quick quenching in the

Diffusion coating of metal products with a sodium-containing bath will reduce the migration of carbon

a calcium, strontium, barium, magnesium or 60 lenstoff from the base into the diffusion coating

Lithium as a 'metal transfer medium and less- prevented. It has also been found that

at least one diffusing metallic element ent- the surface of the coated metal free of

holding melt, which is characterized by tarnishing that remains when using other

that the product with a detergent on its surface will usually occur, provided that one

adhering coating from the transfer means from 65 in the sense of the invention during the transfer

taken out of the melt and at a temperature and immersion of the product in the

at a temperature above the melting point of sodium in a sodium quenching bath

containing liquid sodium, maintained at the same temperature as the transfer medium on the metal.

receives. It has been found that in cases where the surface of the product during transfer is not completely covered by the transfer medium, the occurrence of tarnishing can be prevented by using a sodium quench bath and coating it Product and the quenching vessel with an inert gas atmosphere, e.g. B. from argon or a mixture made of argon and nitrogen.

According to the method according to the invention beschich- ίο Dead and quenched products can be easily removed after removing them from the quenching bath clean. No organic solvents or abrasives are required for this. Sodium that remains on the quenched product can be removed by steam or strong water jets remove. Any transfer medium still remaining on the surface can then be removed easily by washing with water or dilute acid, such as 10 to 20% nitric acid or 1 to 5% acetic acid, remove. When choosing the detergent for the treated and quenched Products should have the possibility of corrosive attack on the coating or the uncoated Parts of the metal product are considered. Such effects are in known in metal cleaning technology.

When carrying out the method according to the invention, it is advantageous to use the coating and to surround the quench bath with a non-oxidizing or inert atmosphere. Argon will preferred as an inert atmosphere; However, you can also use other gases, such as helium, hydrogen or Use mixtures of argon and nitrogen. The procedure can also be carried out in air; however, in this case it must be carefully monitored to avoid any unusual accumulation immediately detect sodium oxide or sodium hydroxide in the quenching bath.

The preferred quench bath is liquid sodium. However, you can also use mixtures Use sodium and other alkali metals such as potassium, cesium, and rubidium. When metal mixtures are used, the sodium should preferably form the main component of the bath.

In the following examples, parts and percentages relate to unless otherwise stated is, on amounts of weight. The thickness of the coatings on the products is determined in a known manner by metallographic examination or, in the case of chromium-containing coatings on iron, by dissolving it away of iron in concentrated nitric acid and measurement of the no longer supported cover film with determined by a micrometer. The composition of the surface coverings is determined by X-ray fluorescence and, in the case of carbon, determined by a combustion conductivity method. These Analysis is carried out with a conductivity carbon analyzer. This device and these methods are known to the person skilled in the art. The copper-acetic acid salt spray test is carried out according to the ASTM test standard B 368-61T carried out.

example 1

A molten bath is made in a heated iron crucible. The bath contains 93% calcium, 1.5% calcium nitride, 4.5% chromium and small amounts of calcium oxide, nickel, aluminum and other elements commonly found in technical calcium. The crucible is placed in a jacket into which argon is introduced. 6.35 x 12.7 cm and 2.54 mm thick plates of low-carbon, cold-rolled Thomas steel (nominal carbon content 0.05-0.08%) are immersed in the coating bath maintained at 1140 ° C. for 9 minutes and then pulled out. There is now a coating of the transfer medium on the plates. The plates are transferred through by an argon atmosphere in quench tank, which are maintained at temperatures in the range of 60 to 160 ⁰ C. The transfer time varies from 2 to 40 seconds, while the temperature of the plates is 900 to 1100 ° C depending on the length of the transfer time when immersed in the quench bath

In a series of tests, liquid sodium is used as a quenching agent at temperatures of 150 to 160 ° C. In another series of experiments, a hydrocarbon oil at 78 to 130 ° C and in a third series of experiments, a silicone oil used at temperatures of 60 to 120 ⁰ C. After quenching, the panels are cleaned using one of the following methods:

a) The sodium quenched panels are first immersed in cold methyl alcohol washed to remove the sodium and then purified with 13 to 20 weight percent nitric acid.

b) The panels quenched in the other quenchants are first washed in running hot water (60 ° C) and then continue as above described, cleaned with nitric acid.

In all cases the cleaned panels are lightly polished to a satisfactory surface gloss to develop, and then by treating for 4 minutes with 20 percent by weight Nitric acid, which contains 2 percent by weight sodium dichromate, passivated at 68 ° C. Be on it the plates were subjected to the copper-acetic acid salt spray test to determine their resistance to corrosion. The coatings are analyzed for their chromium content by means of X-ray fluorescence. The coating thickness is made by observing a metallographically polished and etched cut with a calibrated micrometer eyepiece equipped metallographic microscope. Examination of the coatings after cleaning shows that the sodium quenched panels are glossy and tarnish free while the plates quenched in silicone oil and hydrocarbon oil show gray to black spots exhibit. The values related to the properties of the coatings and the corrosion test for the various samples can be found in Table I.

Table I.

sample ..: properties of the coating Copper-acetic acid salt spray test after 112 hours Deterrents Developed rust spots 0 «/ O chrome
- Thickness, mm after 16 hours 0 τ-I Sodium. . ^ , 39.9 \; ^? ; 0.0254 0 1 2 Sodium · »· .. "0.0254 0 2 3 ■; sodium ^: 39.3 " ^: . 0.0254 1 0 4th ■ sodium 39.6 0.0254 0 ** 5 sodium 39.4 0.0254 0 ** 6th Hydrocarbon oil * 38.2 0.0254 > 100 ** 7th Hydrocarbon oil * 40.6 0.0254 > 50 ** 8th Hydrocarbon oil * 39.2 0.0254 30th ** 9 Hydrocarbon oil * 38.7 0.0254 60 17th 10 Hydrocarbon oil * 38.0 0.0254 40 * # 11th Silicone oil * 39.0 0.0254 10 H = * 12th Silicone oil * 40.6 0.0254 > 25 * # 13th Silicone oil * 37.0 0.0254 > 25 10 14th Silicone oil * 38.7 0.0254 > 30 15th Silicone oil * 37.3 0.0254 3

* For comparison purposes.
**) Not determined as these values would have been meaningless.

Example 2

The procedure is as in Example 1, but with the plates pulled out of the coating bath be transferred through the air into the quenching baths. This is the transfer time from the coating bath to the quenching bath varies. Liquid sodium is used as a deterrent and the hydrocarbon oil given in Example 1 is used. The mean chromium content and the layer thickness of the covering for the two groups of tiles result from the following Tabel.

Table II

Average chromium content, ° / o

Layer thickness, mm

* For comparison purposes.

With oil

deterred *

31.5
0.023876

Quenched with sodium

30.8
0.023368

The results of the copper-acetic acid salt spray test are given in Table III.

Table III

40

45

Copper-acetic acid salt spray test Developed after Rust spots after Transfer ] oil 112 hours 112 hours time in that With deterred * 20th With sodium 1 Quenching bath after 0 deterred 1 16 hours 3 after 0 Seconds 15th 1 16 hours 0 5 0 7th 0 0 10 1 0 15th 1 0 20th 3 0 25th 0

For comparison purposes.

Claims (4)

Patent claims: 1. Process for the diffusion coating of metal products with a calcium, strontium, Barium, magnesium or lithium as a metal transfer agent and at least one diffusing one Melt containing metallic element, characterized in that that the product with a coating adhering to its surface from the transfer agent taken out of the melt and at a temperature above the melting point of sodium in a liquid containing sodium, is immersed in a quench bath at a temperature below about 300 ° C. 2. The method according to claim 1, characterized in that the quenching bath is kept at a temperature between 100 and 300 ⁰ C and the product is rapidly cooled to a temperature below about 350 ° C. 3. The method according to claim 1 or 2, characterized in that the product within a period of 10 to 30 seconds after removal from the melt into the Quenching bath is transferred. 4. The method according to claim 1 to 3, characterized in that the product in the quenching bath cooled to a temperature below about 350 ° C within about 1 to 3 seconds will.