ES2214316T3 - PROCEDURE FOR THE NITRO-CARBURATION OF METAL PARTS. - Google Patents

Abstract

The invention relates to a known method for nitro-carburization of metal workpieces, whereby the workpieces are treated in a treatment chamber with a treatment atmosphere containing nitrogen, carbon monoxide and hydrogen at treatment temperature, whereby carbon dioxide is used as carbon contributor to generate the treatment atmosphere. The invention aims at modifying said method so as to be able to regulate as much as possible the type and volume of nitride formation. To this end, a gas flow (1; 21) containing carbon dioxide is introduced into a reactor (4; 24) connected upstream from the treatment chamber (6; 27) and modified therein into a carburizing gas (5; 25) by reaction with a hydrogen contributor (2; 22) at a reaction temperature above treatment temperature, said gas having a higher carbon activity at treatment temperature than the gas flow (1; 21) containing carbon dioxide.

Description

Procedure for nitro-carburetion of metal parts.

The invention relates to a process for nitro-carburetion of metal parts, in which the pieces are treated in a treatment atmosphere, which contains nitrogen, carbon monoxide and hydrogen, at a temperature of treatment, within a treatment room, using carbon dioxide as a carbon donor for the production of the treatment atmosphere

For nitro carburetion of different metal parts are used different gas mixtures. The Nitrogen donor is, in this case, essentially ammonia (NH3), while as a carbon donor they are used different gas mixtures, such as air mixtures and hydrocarbons (endogas and exogás) as well as carbon dioxide. In the nitriding furnace, these gases react with hydrogen present, realizing that, depending on what the thermal and chemical conditions, an activity is adjusted stationary carbon, nitrogen and oxygen.

Atomic nitrogen, which is formed when the ammonia splitting, when coming into contact with surfaces metallic (hereinafter referred to as (N) ad) reacts especially easily with metal, mediating nitride formation. Together with iron they can form Different phases of nitrides. In the case of steels, in attention to obtain high hardness and high wear resistance, it they prefer, for example, nitride phases in the form of called nitride? (Fe_2-3) and nitride γ '(Fe 4 N) or mixtures of these nitrides. The reactions, which develop during nitride formation of metals containing Fe, can be described schematically with help of the following chemical equations:

(1) NH3 = (N) ad + 1.5 \ H2

\hskip1.8cm

(nitruro \gamma')(2a) (N) ad + 4 Fe = Fe 4 N

 \ hskip1.8cm 

(nitride γ ')

\hskip1cm

(nitruro \varepsilon)(2b) (N) ad + 2-3 Fe = Fe_ 2-3 N

 \ hskip1cm 

(nitride \ varepsilon)

The carbon dissolved in the nitride has an impact on morphology, compactness, pore seam and adhesion of the bonding layer, and its stability against corrosion and to wear In addition, it has been shown that through  carbon activity in the nitriding atmosphere is influenced essentially about the type and extent of the formation of nitrides Carbon activity, in turn depends on what the carbon donor used. This decreases in the order of succession of propane, endogas, exogas and carbon dioxide. Market Stall that the composition of the gas phase in the nitriding furnace therefore has an essential influence on the result of nitrocarburization, it is favorable that this be adjustable within intervals as wide as possible possible.

In the cases of known gaseous mixtures, carbon dioxide contents are usually located between 4 and 10% by volume. Carbon dioxide is introduced dosed directly in the oven enclosure of nitriding and reacts there partially with hydrogen from according to the following reaction equation:

(3) CO 2 + H 2 = CO + H2O

Usually, the nitriding furnace is traveled permanently with a new contribution gas, so that in the gas phase no chemical equilibrium is adjusted. I know establish with this a stationary carbon activity (a_ {c, B}), which depends essentially on the specific data in the nitriding furnace, such as for example the surface of the parts to be treated, the nitriding temperature, the gas composition and volumetric gas flow rate, and hardly You can regulate from the outside. Therefore, it fits oscillatingly a carbon activity (a_ {c, B}) that is adapted to the predominant data, and that can be defined as according to Bouduard's reaction:

2 \ CO = C + CO 2

(a_ {c, B}) = K_ {B} \ text {*} P2} {} _ {co} / P_ {co2}

K_ {B} designates in this case the constant of Bouduard balance. When feeding carbon dioxide directly in the nitriding furnace, an activity of carbon of maximum 1, which corresponds to an activity of pure graphite Under these conditions, nitride formation ε (Fe_ {2-3} N) can be performed without However, only a high nitriding characteristic index (K_ {N}) greater than 1.

In response to this, refer to German patent document DE-C1 197 19 225, from which know a procedure for index regulation characteristic of a nitriding atmosphere or nitro-carburetion in an oven installation, in the case of using NH3 as a nitrogen source. The known procedure is distinguished by the fact that the flow rate of NH3 gas remains constant, and only the point of work of the previous splitter, in which the gas is produced of unfolding of NH3. A high characteristic index of nitriding requires a high ammonia content in the furnace of nitriding, which in turn results in a high remaining ammonia content in the furnace outlet gas, which Leave the oven unused.

This effect is also established in the case of procedure proposed in the patent application document German DE-A1 42 29 803, according to which the characteristic nitriding index for the control of a nitriding or nitrocarburizing atmosphere, the characteristic nitriding index being determined by measurement of the O2 content of the atmosphere through the use of an O2 probe.

In document DE-A1 195 14 932, in order to produce an atmosphere of carbo nitriding is proposed to contribute directly to the hydrocarbon furnace and an oxidizing component, such as air or CO 2, and ammonia. In order to get regulated content of CO, as high as possible in the carbon atmosphere nitriding, the CO content is measured, and when a limit is reached Previously established bottom is fed into the enclosure of the Oven a substance that forms CO, such as methanol. In the case of this procedure, the components that form CO, such as methanol or CO2 are therefore fed directly inside the treatment room. When carbureting or carbo nitride, this is effective because of the high temperatures that predominate in this case, but it is not in the case of the usual nitriding temperatures, relatively low, of maximum 580ºC. At these lower temperatures, the Methanol does not unfold stoichiometrically, but rather forms unwanted splitting products, such as CH4 and others higher hydrocarbons, CO2, aldehydes, ketones, etc., than in part are poisonous, and are corrosive during condensation. In addition, the splitting of methanol is largely dependent. of the data of the heating enclosure and the surface of the load, so that the desired reproducibility is not presented gaseous composition of the oven. This also has as a consequence the fact that through uncontrolled reactions of unfolding soot is deposited on the load material and on the surface of the heating enclosure, or they are formed unwanted carbides.

The invention is therefore based on the mission of modifying the known procedure for nitro-carburetion of metal parts mediating use of carbon dioxide as a carbon donor, in such a way that can be adjusted within a broad framework type and extension of nitride formation.

The problem posed by this mission is resolves, according to the invention, by the recourse that a gaseous stream containing carbon dioxide is introduced into a reactor arranged in front of the treatment room, and there is modified by reaction with a hydrogen donor at a reaction temperature above the temperature of treatment to form a carburetion gas, which presents the treatment temperature a higher carbon activity in comparison with the gas stream containing dioxide carbon.

The gas stream containing dioxide carbon is supplied according to the invention to a reactor, there it is modified in the direction of obtaining a higher carbon activity and then it is introduced as carburetion gas in the enclosure of treatment.

The procedure is explained with the help of the Figure 1 and Figure 2.

The procedure for nitro-carburetion of metal parts, in which metal parts are treated in a treatment atmosphere that contains nitrogen, carbon monoxide and hydrogen, at a treatment temperature inside a treatment room, being used, for the production of the treatment atmosphere, carbon dioxide as a carbon donor, is characterized because a gas stream 1, 21, which contains dioxide of carbomo, is introduced into a reactor 4, 24 arranged in front of the treatment room 6, 27, and there it is modified by reaction with a hydrogen donor 2, 22, at a reaction temperature located above the treatment temperature to form a gas of carburetion 5, 25, which presents a treatment temperature higher carbon activity compared to that of the current Soda 1, 21 containing carbon dioxide.

In the case of the procedure it is used as hydrogen donor a fluid 2 containing hydrocarbons, in In particular, natural gas, propane or methane 2 is used as a donor of hydrogen. In the case of another procedure, ammonia is used as a hydrogen donor.

In the case of the procedure, in which as hydrogen donor is used ammonia 22, is used as a reactor in particular an unfolding apparatus 24 for ammonia. In in particular, in the case of the process moisture is subtracted from carburetion gas 5, 25 before its introduction into the enclosure of treatment 6, 27.

In the case of the procedure, it is planned preferably a regulation arrangement 9, 30 for the carbon activity in the treatment room 6, 27, in which case as the magnitude of adjustment serves the regime of contribution of a partial current containing the hydrogen donor 2, 22. The regulation provision 9, 30 for carbon activity it comprises a measurement of oxygen activity 8, 29 and / or of the concentration of carbon monoxide in the treatment room 8, 27. With the gas stream 1, 21 containing carbon dioxide, with carburetion gas 5, 25 and / or with partial current to the hydrogen donor 2, 22 mixes in particular a gas of dilution 3, 23.

In the case of the procedure, the gas from carburation 25, before its introduction into the enclosure of treatment 27, preferably cooled to a temperature located in the range of the treatment temperature.

In the case of the procedure, preferably, carburetion gas 5, upon introduction into the treatment room 6, has a temperature located in the reaction temperature range.

In the case of the procedure, the temperature of treatment is preferably located in the range between 500ºC and 700ºC.

In the case of the procedure, the temperature of reaction is preferably located in the range between 800 and 1,150 ° C.

Claims (13)

1. Procedure for nitro-carburation of metal parts, in which the parts are treated in a treatment atmosphere containing nitrogen, carbon monoxide and hydrogen, at a treatment temperature within a treatment room, using carbon dioxide as a carbon donor for the production of the treatment atmosphere, characterized in that a gaseous stream containing carbon dioxide (1; 21) is introduced into a reactor (4; 24) arranged in front of the treatment room (6; 27) and there it is modified by reaction with a hydrogen donor (2; 22) at a reaction temperature above the treatment temperature to form a carburetion gas (5; 25), which has a higher carbon activity compared with that of the gas stream containing carbon dioxide (1; 21) at the treatment temperature. 2. A method according to claim 1, characterized in that a hydrocarbon-containing fluid (2) is used as hydrogen donor. 3. Method according to claim 1 or 2, characterized in that a natural gas, propane or methane (2) is used as hydrogen donor. 4. Method according to claim 1, characterized in that ammonia is used as hydrogen donor (22). 5. Method according to claim 4, characterized in that a splitting apparatus (24) is used as a reactor for ammonia. Method according to claim 4 or 5, characterized in that moisture is subtracted from the carburetion gas (5; 25) before it is introduced into the treatment room (6; 27). 7. Method according to one of claims 1 to 6, characterized in that a regulation arrangement (9; 30) for carbon activity is provided in the treatment room (6; 27), in which as an adjustment quantity the rate or rate of contribution of a partial stream containing the hydrogen donor (2; 22) serves. Method according to claim 7, characterized in that the regulation arrangement (9; 30) for carbon activity comprises a measurement of oxygen activity (8; 29) and / or of the concentration of carbon monoxide in the treatment room (6; 27). 9. Method according to one of claims 7 or 8, characterized in that with the gas stream containing carbon dioxide (1; 21), with the carburation gas (5; 25) and / or with the partial stream for the hydrogen donor (2; 22) a dilution gas (3; 23) is mixed. Method according to one of claims 1 to 9, characterized in that the carburetion gas (25), before being introduced into the treatment room (27), is cooled to a temperature in the range of the temperature of treatment. Method according to one of claims 1 to 9, characterized in that the carburation gas (5), before being introduced into the treatment room (6), has a temperature in the range of the reaction temperature. 12. Method according to one of claims 1 to 11, characterized in that the treatment temperature is in the range between 500 ° C and 700 ° C. 13. Method according to one of claims 1 to 12, characterized in that the reaction temperature is in the range between 800 and 1,150 ° C.